From eyedrops to potential leukaemia treatment

   
   
 Eye
19 Dec 2018 10:00:00.000

PA 277/18

An active ingredient in eye drops that were being developed by experts in Nottingham has shown promise for treating an aggressive form of blood cancer, research has shown.

Researchers from the University of Nottingham worked on the research led by scientists at the Wellcome Sanger Institute, University of Cambridge, and other collaborators which found that the compound, which targets an essential cancer gene, could kill leukaemia cells without harming non-leukemic blood cells.

The results, published today (19 December) in Nature Communications, reveal a potential new treatment approach for an aggressive blood cancer with a poor prognosis.

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Acute myeloid leukaemia (AML) is a form of blood cancer that affects people of all ages, often requiring months of intensive chemotherapy and prolonged hospital admissions. It develops in cells in the bone marrow crowding out the healthy cells, in turn leading to life-threatening infections and bleeding.

Mainstream AML treatments have remained unchanged for more than 30 years, with the current treatment being chemotherapy, and the majority of people’s cancer cannot be cured. A subtype of AML, driven by rearrangements in the MLL gene has a particularly bad prognosis.

The latest study centres on the gene SRPK1, which is a key target for a new eye drop developed by the University of Nottingham biotech spin-out business Exonate for the treatment of the eye disease wet Age-related Macular Degeneration (AMD).

In a previous study, researchers at the Sanger Institute developed an approach, based on CRISPR gene editing technology, which helped them identify more than 400 genes as possible therapeutic targets for different subtypes of AML. SRPK1, was found to be essential for the growth of MLL-rearranged AML. SRPK1 is involved in a process called RNA splicing, which prepares RNA for translation into proteins, the molecules that conduct the majority of normal cellular processes, including growth and proliferation.

In the new study, Sanger Institute researchers and their collaborators set out to work out how inhibition of SRPK1 can kill AML cells and whether it has therapeutic potential in this disease. They first showed that genetic disruption of SRPK1 stopped the growth of MLL-rearranged AML cells and then went on to study the compound SPHINX31, an inhibitor of SRPK1, that was being used to develop a new drug for an eye drop treatment for retinal neovascular disease – the growth of new blood vessels in the retina that can bleed spontaneously and cause vision loss.

The team found that the compound strongly inhibited the growth of several MLL-rearranged AML cell lines but did not inhibit the growth of normal blood stem cells. They then transplanted patient-derived human AML cells into immunocompromised mice and treated them with the compound. Strikingly, the growth of AML cells was strongly-inhibited and the mice did not show any noticeable side effects.

Dr George Vassiliou, joint leader of the research from the Wellcome Sanger Institute and the Wellcome-MRC Cambridge Stem Cell Institute, said: “We have discovered that inhibiting a key gene with a compound being developed for an eye condition can stop the growth of an aggressive form of acute myeloid leukaemia without harming healthy cells. This shows promise as a potential approach for treating this aggressive leukaemia in humans.”

SRPK1 controls the splicing* of RNA in the production of new proteins. An example of a gene that is affected when SRPK1 is blocked is BRD4, a well-known gene that maintains AML. Inhibiting SRPK1 causes the main form of BRD4 to switch to another form, a change that is detrimental to AML growth.

Dr Konstantinos Tzelepis, joint lead author from the Wellcome Sanger Institute and University of Cambridge, said “Our study describes a novel mechanism required for leukaemia cell survival and highlights the therapeutic potential of SRPK1 inhibition in an aggressive type of AML. Targeting this mechanism may be effective in other cancers where BRD4 and SRPK1 play a role, such as metastatic breast cancer.”

Professor David Bates, from the University of Nottingham’s School of Medicine and co-founder of Exonate, said: “When Dr Vassiliou told me that SRPK1 was required for the survival of a form of AML, I immediately wanted to work with him to find out if our inhibitors could actually stop the leukaemia cells growing. The fact that the compound worked so effectively bodes well for the development of SRPK1 inhibitors as a new therapy for leukaemia. It will take some time, but there is real promise for a new treatment on the horizon for patients with this aggressive cancer.”

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Notes to editors: 

The University of Nottingham is a research-intensive university with a proud heritage, consistently ranked among the world's top 100. Studying at the University of Nottingham is a life-changing experience and we pride ourselves on unlocking the potential of our 44,000 students - Nottingham was named both Sports and International University of the Year in the  2019 Times and Sunday Times Good University Guide, was awarded gold in the TEF 2017 and features in the top 20 of all three major UK rankings. We have a pioneering spirit, expressed in the vision of our founder Sir Jesse Boot, which has seen us lead the way in establishing campuses in China and Malaysia - part of a globally connected network of education, research and industrial engagement. We are ranked eighth for research power in the UK according to REF 2014. We have six beacons of research excellence helping to transform lives and change the world; we are also a major employer, proud of our Athena SWAN silver award, and a key industry partner- locally and globally.

 

*Splicing is the preparation of RNA for the production of proteins. From the strand of RNA, non-coding regions (introns) are removed, leaving the coding regions (exons) which are needed for the assembly of amino acids to form proteins.

Publication: Konstantinos Tzelepis et al. (2018) SRPK1 maintains acute myeloid leukemia through effects on isoform usage of epigenetic regulators including BRD4. Nature Communications. DOI: 10.1038/s41467-018-07620-0

Funding: This study was supported by Wellcome (WT098051 and RG94424), the Kay Kendall Leukaemia Fund (KKL920), Cancer Research UK and Exonate Ltd.

Story credits

More information is available from Professor David Bates in the School of Medicine, University of Nottingham on +44 (0)115 823 1135, david.bates@nottingham.ac.uk

Emma Thorne Emma Thorne - Media Relations Manager

Email: emma.thorne@nottingham.ac.uk Phone: +44 (0)115 951 5793 Location: University Park

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