Researchers from The University of East Anglia (UEA) have contributed to the world’s largest study into genes that drive prostate cancer – identifying 80 molecular weaknesses that could be targeted by drugs to treat the disease.
The Cancer Genetics Team at Norwich Medical School, UEA, led by Prof Colin Cooper and Dr. Dan Brewer, have played an active role in this research, performing mathematical analyses, providing scientific insight and helping to lead the study.
Around a quarter of the gene mutations identified involve the targets of existing drugs that are either licensed or in clinical trials – suggesting that these could offer promise for further study as new approaches to treatment.
And the landmark research also opened up 60 new potential lines of attack against prostate cancer for future investigation, as well as identifying many new genes associated with the development of the disease.
Around 34 institutions from across the UK and internationally, analysed tumour genetics of nearly a thousand patients with prostate cancer, alongside a wealth of drug data.
The study is published in the journal Nature Genetics, and was largely funded by Cancer Research UK.
The researchers obtained genetic information from the tumours of 112 men with prostate cancer and pooled it with data from other studies, together analysing samples from 930 prostate cancer patients.
They combined detailed genetic analysis with the latest Big Data approaches to identify large numbers of genetic changes that underlie the development and spread of prostate cancer. They then took this genetic information and drew up a map of the network of associated proteins.
Using canSAR, a comprehensive database for cancer drug discovery, they found that 80 of the proteins in the network were possible drug targets.
Some 11 of these were targeted by existing licensed drugs and seven by drugs in clinical trials, while 62 were identified as potential targets to explore.
While further research is needed before the potential new targets could be explored in clinical trials, the new study has opened up many potential ways of targeting the disease.
For example, the research raised the possibility that BRAF and ATM proteins could be targeted in prostate cancer – and research is already under way in these areas.
The team also established a timeline of genetic changes in prostate cancer, which could in future improve ways to spot the disease – as current methods of diagnosis, such as PSA testing, are unreliable.
The timeline could also help predict the way prostate cancer evolves in individual patients, which might allow treatment to be adapted to combat drug resistance.
Joint project lead, Professor Colin Cooper, Chair of Cancer Genetics at Norwich Medical School, UEA, said:
“The treatment of prostate cancer represents a significant global health problem, so it was great that experts from UEA were able to play a leading role in this pioneering research.
“The study provides an important step towards personalising treatment for men with prostate cancer. We have identified many pathways by which this cancer develops, for which new drugs can be used to disrupt those pathways and potentially improve treatment.”
Study leader Professor Ros Eeles, Professor of Oncogenetics at The Institute of Cancer Research, London, said:
“Our study applied cutting-edge techniques in Big Data analysis to unlock a wealth of new information about prostate cancer and possible ways to combat the disease.
“One of the challenges we face in cancer research is the complexity of the disease and the sheer number of ways we could potentially treat it – but our study will help focus our efforts on the areas that offer most promise for patient benefit.”
Study co-author Professor Paul Workman, Chief Executive of The Institute of Cancer Research, London, said:
“This study has uncovered a remarkably large number of new genes that drive the development of prostate cancer, and given us vital information about how to exploit the biology of the disease to find potential new treatments.
“We hope our findings will stimulate a wave of new research into the genetic changes and potential drug targets we have identified, with the aim that patients should benefit as soon as possible.”
Dr. Justine Alford from Cancer Research UK, said:
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