Researchers find that new targeted drugs can attack weak spots in cancer cells

Scientists have identified weak spots in cancer cells that could be targeted and attacked by new precision drugs.

A major computational analysis by scientists at the University of Sussex and The Institute of Cancer Research, London, has found a number of potential targets for drugs that exploit the inherent weaknesses of cancer cells.

The findings could lead to personalised medicine that 'reads' a cancer patient's DNA and only attacks defective cells - in contrast to the scattergun approach of conventional chemotherapy, which attacks all dividing cells, including healthy ones.

The study is published today (Tuesday 24 February 2015) in the journal Nature Reviews Cancer.

Scientists from the University of Sussex and The Institute of Cancer Research (ICR) analysed the patterns of mutations found in the DNA sequences of tumours from more than 5,000 cancer patients.

The team, jointly led by Dr Frances Pearl (Sussex) and Dr Bissan Al-Lazikani (ICR), focused on the 'DNA repair' systems that protect the genetic information of the cell, and are mutated in almost all cancers. Breaking these systems for DNA repair allows cancer cells to divide uncontrollably and generate even more mutations - helping them become resistant to chemotherapy and radiation treatments.

"Knowing which DNA repair processes are defective in an individual tumour allows us to target new drugs that are only toxic to cells with a particular pattern of mutations - ie cancer cells," said Dr Pearl, who heads the Bioinformatics Research Group at Sussex.

One class of drug called PARP inhibitors already target DNA repair systems. They are being used in clinical trials to treat women with breast or ovarian cancers that have mutations in BRCA genes, and one of the class, olaparib, has recently been licensed for women with ovarian cancer in Europe and the US.

But the development of new targeted drugs like these relies on identifying good targets. It is only because of huge advances in technology that such a large-scale analysis is now possible.

By using cutting edge computing techniques, the team have been able to examine much larger data sets than ever before. Dr Pearl said: "This analysis shows that there are many other cancers where new targeted drugs could selectively kill tumours with DNA repair defects.

"This potentially means thousands more cancer patients could be saved from the horrible side-effects of chemotherapy by receiving precision medicine, which doesn't kill the body's healthy cells."

Study co-leader Dr Bissan Al-Lazikani, Team Leader in Cancer Therapeutics at The Institute of Cancer Research, London, said:

"Only a small fraction of the proteins involved in cancer are targeted by current drugs, and we urgently need drugs that hit new targets. DNA repair proteins hold particular promise as new drug targets, and there are already some drugs coming through that exploit cancer's inherent weaknesses in DNA repair.

"Using 'big data' analysis, our study has identified untargeted DNA repair proteins that look especially promising as the targets for new anti-cancer drugs. Such drugs would not only prove useful in their own right, but also potentially in combination with radiotherapy or other drugs to overcome treatment resistance. We hope this study will help speed up the development of new personalised cancer treatments."

The University of Sussex is home to the world-leading Genome Damage and Stability Centre, one of the largest concentrations of scientists studying DNA repair in the world. Centre Director Professor Tony Carr said: "Understanding the responses of cells to genome damage is critical in our fight to beat cancer and other life-threatening diseases.

"The University of Sussex is playing a vital role in this war against cancer, not just through cutting edge scientific discovery but through the work of our drug discovery colleagues at Sussex and ICR who are creating new medicines that have a real impact in the treatment and diagnosis of major human diseases.

"The more we discover, the more intelligent our weapons against cancer become, and the closer we get to the day when cures for this major killer will be found."

The Institute of Cancer Research, London, discovers more new cancer drugs than any other academic centre in the world. Since 2005, the Institute of Cancer Research (ICR) has successfully discovered 17 drug candidates, and progressed seven drugs discovered at the ICR into clinical trials.

Professor Paul Workman, Chief Executive of The Institute of Cancer Research, London, said:

"It is faults in their DNA repair systems that allow cancer cells to accumulate mutations so rapidly, and to evolve in ways that make them hard to treat. But these deficiencies in DNA repair can also leave cancers vulnerable to attack, and this analysis shows how we could design drugs to further weaken cancer cells' repair systems - and drive them to their deaths."

Professor Laurence Pearl, Head of the School of Life Sciences at the University of Sussex, and a co-author of the research, commented: "I am particularly delighted with the burgeoning collaboration between world-class research groups at Sussex and ICR which will be critical to bringing forward a new class of anti-cancer drugs to target the DNA damage response."

Comments

  1. Vadim Shapoval Vadim Shapoval Ukraine says:

    Professor Paul Workman, Chief Executive of the ICR, said: A lot of the genetic variants already linked to cancer occur in gene deserts - often very long and quite mysterious DNA sequences that don't actually contain 'genes', but which are involved in causing cancer in ways we do not yet fully understand. Speaking at the World Oncology Forum in Switzerland, Professor claimed theoretical scientists have identified 500 cancer-related proteins which could be attacked by drugs - but only 5 per cent of these treatments have so far been developed. A major problem, he admitted, is finance. Today, militaristic language (the War on Cancer) pops up in oncology. The Father of Oncology said: Scientific iron/cancer information-1905-2015 is largely ignored. Researchers cannot understand that primary tumors always develop at body sites of excessive iron deposits. Such deposits can be inherited or acquired (local/regional iron overload can be inherited or acquired). Cancer is a disease of iron-overloaded cells. Every person has cancer genes (iron-overloaded genes) and anticancer genes (iron-deficiency genes). At the cellular level, cancer occurs when cellular iron overload chaotically affects DNA, chromosomes, mitochondria, lysosomes, etc. DNA carries the instructions for building all of the proteins that make each living creature unique. Abnormalities in the DNA are like typographical errors. Some errors lead to production of a slightly abnormal protein, while others lead to a very abnormal protein or to the complete absence of a particular protein. Surgery (ceramic blades), direct intratumoral injections of iron-deficiency agents (ceramic needles) and personalised clinical iron-deficiency methods can successfully eliminate tumors, metastases and micrometastases. Cancer costs the world economy nearly US$3 trillion every year. Will we ever win the War on Cancer? We are surrounded by a growing ocean of cancer information in all formats. Information overload is used to suppress adequate information on cellular iron overload and anticancer iron-deficiency methods.

The opinions expressed here are the views of the writer and do not necessarily reflect the views and opinions of News Medical.
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