Public Release:  New study explains how dense breast tissue drives the early stages of cancer

Landes Bioscience

Scientists from The University of Manchester working with IBM Research have identified a key biological mechanism that for the first time explains why women with dense breast tissue are at greater risk of developing breast cancer.

The research, published today in the journal Cell Cycle, has important implications for future cancer prevention and treatment.

Women with higher breast density--detected on mammograms--have more compacted breast tissue and are more likely to develop breast cancer, but until now the reasons for this have been unclear.

Manchester scientists, funded by leading UK research organization Breakthrough Breast Cancer, worked with IBM researchers and academics in the USA and Cyprus to uncover the biological mechanisms at play. Their findings could help to improve breast cancer prevention by targeting these specific biological mechanisms with cancer therapies in at-risk patients and could potentially lead the way for a new strategy for the use of preventative treatments.

Professor Michael Lisanti, from The University of Manchester, part of Manchester Cancer Research Centre, said, "We know that high breast density can greatly increase a woman's breast cancer risk as well as other factors such as aging, family history, and presence of mutations in genes such as BRCA 1 and BRCA 2.

"What no one has fully appreciated before are the underpinning mechanisms at play. Using a bioinformatics approach, we have identified the relevant signaling pathways that make dense breast tissue more favorable for tumor formation.

"This signaling pathway could be used as a biomarker to identify women at higher risk of breast cancer more accurately and earlier than the current methods. Furthermore, there are drugs out there that block these pathways, so that these women could be offered effective chemoprevention."

The researchers used structural cells, called fibroblasts, from high-density breast tissue to generate a molecular signature. This signature showed that a cellular communication network called JNK1 was activated to a greater extent in fibroblasts from high-density breast tissue. The JNK1 network is known to instruct cells to release chemicals that create an inflammatory environment, and inflammation is known to be a driver of tumor formation.

The study team explained that blocking the JNK1 network could feasibly reduce the risk of, and potentially prevent, breast cancer in women with high density breast tissue. Interestingly, the molecular signature of the fibroblasts isolated from high density tissue also matched the fibroblasts found in breast tumors, meaning drugs that interfere with the JNK1 network could also potentially act as a treatment for women who already have breast cancer.

Dr Federica Sotgia, from The University of Manchester's Institute of Cancer Sciences and joint-senior author on the paper, said, "This research expands on the early work by the London surgeon Stephen Paget, who proposed the 'seed and the soil' hypothesis, now over 125 years ago. In this paradigm, the 'seeds' are the cancers cells and the 'soil' is the tissue in which they grow.

"Our research has identified the right soil for seeds to flourish by looking at the microenvironment in the breast and examining the mechanisms at play. This can help us with designing new preventative trials, to develop and test new therapies, which might prevent progression on to cancer.

"Current cancer treatment often focuses on targeting cancer cells but is not focused on targeting the fibrotic connective tissue, that may develop first, before you have cancer."

The researchers now plan to team up with other world-leading experts in cancer signaling based in Manchester including Professor Nic Jones, Director of MCRC and Cancer Research UK Chief Scientist who heads the Cell Regulation Laboratory, which studies how cells respond to sudden adverse changes in their surroundings, known as environmental stress. They will also team up with Professor Tony Howell who specializes on breast density.

Aristotelis Tsirigos, computational biology researcher from IBM, said, "These results are very exciting. It suggests a new pathway to target in the microenvironment for cancer cells." Scientists at the Computational Biology Center in IBM Research provided analytics tools and performed analysis of the data to help tease out the biological mechanisms at play in studying the micro-environment of breast cancer cells. As biological data is becoming more abundant and available, data-driven analytics methods and high-performance computing systems are becoming more useful in suggesting novel hypotheses for life sciences experiments and discovery.

Professor Howell, based at the Genesis Breast Cancer Prevention Centre at University Hospital of South Manchester, and at The University of Manchester, said, "At least 50 per cent of cancer risk is genetic, but activated cell stress signaling could potentially be reduced by dietary or lifestyle intervention. This research should help with a cancer prevention strategy, rather than waiting to treat the cancer once it arrives."

Professor Jones said, "This analysis of breast density provides a new framework for additional experimental exploration in breast cancer research. This has important clinical and translational implications for stratified medicine and breast cancer prevention."

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The paper entitled "JNK1 stress signaling is hyper-activated in high breast density and the tumor stroma: Connecting fibrosis, inflammation, and stemness for cancer prevention" is published in Cell Cycle on 15th February 2014 and is available online now at https://www.landesbioscience.com/journals/cc/article/27379/.

About The University of Manchester

The University of Manchester, a member of the Russell Group, is one of the largest and most popular universities in the UK. It has 20 academic schools and hundreds of specialist research groups undertaking pioneering multi-disciplinary teaching and research of worldwide significance. According to the results of the 2008 Research Assessment Exercise, The University of Manchester is one of the country's major research institutions, rated third in the UK in terms of "research power." The University has an annual income of £807 million and is ranked 40th in the world and fifth in the UK for the quality of its teaching and impact of its research.

About Breakthrough Breast Cancer

  • Breakthrough Breast Cancer is the UK's leading breast cancer charity dedicated to saving lives through improving early diagnosis, developing new treatments and preventing all types of the disease.

  • The need for Breakthrough Breast Cancer's work has never been greater. Breast cancer is the most common of all cancers in the UK, with 50,000 women diagnosed every year and 1,000 women dying every month.

  • Breast cancer is not yesterday's problem; it's a disease that affects more women every year. Breakthrough Breast Cancer is working harder than ever before to stop women getting, and dying from, the disease.

  • The charity funds 25% of the breast cancer research in the UK, campaigns to ensure survival rates are among the best in the world and educates women to recognise the signs and symptoms of the disease. Breakthrough Breast Cancer's vision is a world freed from breast cancer.

  • For more information go to breakthrough.org.uk

Twitter: @BreakthroughBC / Facebook: Breakthrough Breast Cancer / YouTube: Breakthrough Breast Cancer

About IBM

For more information on IBM Research visit http://www.research.ibm.com.

About Landes Bioscience

In addition to the cell cycle and cell division, Cell Cycle covers all topics from man to virus, from DNA to RNA, from aging to development, from cell senescence to stem cells, from apoptosis to autophagy, from cancer to neurobiology, from molecular and theoretical biology to medicine and therapy. Established in 1997, Landes Bioscience is an Austin, Texas-based publisher of biology research journals and books. For more information on Landes Bioscience, please visit http://www.landesbioscience.com/.

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