DNA of 50 breast cancer patients decoded

Reveals complexity and hints toward personalized medicine

In the single largest cancer genomics investigation reported to date, scientists have sequenced the whole genomes of tumors from 50 breast cancer patients and compared them to the matched DNA of the same patients’ healthy cells. This comparison allowed researchers to find mutations that only occurred in the cancer cells.

They uncovered incredible complexity in the cancer genomes, but also got a glimpse of new routes toward personalized medicine. The work was presented at the American Association for Cancer Research 102nd Annual Meeting 2011.

In all, the tumors had more than 1,700 mutations, most of which were unique to the individual, says Matthew J. Ellis, MD, PhD, professor of medicine at Washington University School of Medicine in St. Louis and a lead investigator on the project.

“Cancer genomes are extraordinarily complicated,” Ellis says. “This explains our difficulty in predicting outcomes and finding new treatments.”

To undertake the massive task, Washington University oncologists and pathologists at the Alvin J. Siteman Cancer Center at Barnes-Jewish Hospital and Washington University School of Medicine collaborated with the university’s Genome Institute to sequence more than 10 trillion chemical bases of DNA — repeating the sequencing of each patient’s tumor and healthy DNA about 30 times to ensure accurate data.

“The computing facilities required to analyze this amount of data are similar in scale to those of the Large Hadron Collider, used to understand the workings of sub-atomic particles,” Ellis says.

The DNA samples came from patients enrolled in a clinical trial that Ellis is leading for the American College of Surgeons Oncology Group. All patients in the trial had what is called estrogen-receptor-positive breast cancer. These cancer cells have receptors that bind to the hormone estrogen and help the tumors grow.

To slow tumor growth and make the tumors easier to remove, patients received estrogen-lowering drugs before surgery. But, for unknown reasons, this treatment does not always work. Twenty-four of the 50 tumor samples came from patients whose tumors were resistant to this treatment, and 26 came from patients whose tumors responded. Comparing the two groups might help explain why some estrogen-receptor-positive breast cancer patients do well with estrogen-lowering drugs and others poorly.

Confirming previous work, Ellis and colleagues found that two mutations were relatively common in many of the patients’ cancers. One called PIK3CA is present in about 40 percent of breast cancers that express receptors for estrogen. Another called TP53 is present in about 20 percent.

Adding to this short list of common mutations, Ellis and colleagues found a third, MAP3K1, that controls programmed cell death and is disabled in about 10 percent of estrogen-receptor-positive breast cancers. The mutated gene allows cells that should die to continue living. Only two other genes, ATR and MYST3, harbored mutations that recurred at a similar frequency as MAP3K1 and were statistically significant.

“To get through this experiment and find only three additional gene mutations at the 10 percent recurrence level was a bit of a shock,” Ellis says.

In addition, they found 21 genes that were also significantly mutated, but at much lower rates — never appearing in more than two or three patients. Despite the relative rarity of these mutations, Ellis stresses their importance.

“Breast cancer is so common that mutations that recur at a 5 percent frequency level still involve many thousands of women,” he says.

Ellis points out that some mutations that are rare in breast cancer may be common in other cancers and already have drugs designed to treat them.

“You may find the rare breast cancer patient whose tumor has a mutation that’s more commonly found in leukemia, for example. So you might give that breast cancer patient a leukemia drug,” Ellis says.

But such treatment is only possible when the cancer’s genetics are known in advance. Ideally, Ellis says, the goal is to design treatments by sequencing the tumor genome when the cancer is first diagnosed.

“We get good therapeutic ideas from the genomic information,” he says. “The near-term goal is to use information on whole genome sequencing to guide a personalized approach to the patient’s treatment.”

This work builds on previous collaborations between Washington University oncologists and the Genome Institute. In a study published last year in Nature, they reported the complete tumor and normal DNA sequences of a woman with “triple-negative” breast cancer, a particularly aggressive type that is difficult to treat and more common in younger women and African-Americans.

While many mutations are rare or even unique to one patient, Ellis says quite a few can be classified on the basis of common biological effects and therefore could be considered together for a particular therapeutic approach.

Ellis looks to future work to help make sense of breast cancer’s complexity. But these highly detailed genome maps are an important first step.

“At least we’re reaching the limits of the complexity of the problem,” he says. “It’s not like looking into a telescope and wondering how far the universe goes. Ultimately, the universe of breast cancer is restricted by the size of the human genome.”


Ellis et al. Breast cancer genome. Presented Saturday, April 2, 2011, at the 102nd Annual Meeting of the American Association for Cancer Research in Orlando, Fla.

Ding L, Ellis MJ, Weinstock GM, Aft R, Watson M, Ley TJ, Wilson RK, Mardis ER et al. Cancer remodeling in a basal-like breast cancer metastasis and xenograft. Nature. April 15, 2010.

This work was supported by grants from the National Human Genome Research Institute, the Breast Cancer Research Foundation, the National Cancer Institute, Susan G. Komen for the Cure and Washington University School of Medicine.

Washington University School of Medicine’s 2,100 employed and volunteer faculty physicians also are the medical staff of Barnes-Jewish and St. Louis Children’s hospitals. The School of Medicine is one of the leading medical research, teaching and patient care institutions in the nation, currently ranked fourth in the nation by U.S. News & World Report. Through its affiliations with Barnes-Jewish and St. Louis Children’s hospitals, the School of Medicine is linked to BJC HealthCare.

Alvin J. Siteman Cancer Center is the only NCI-designated Comprehensive Cancer Center within a 240-mile radius of St. Louis. Siteman Cancer Center is composed of the combined cancer research and treatment programs of Barnes-Jewish Hospital and Washington University School of Medicine.

One of only three NIH-funded large-scale genome centers in the United States, The Genome Institute at Washington University is a leader in genomics research as it applies to the study of biology, human disease and the field of personalized medicine. Founded in 1993, The Genome Institute focuses on cancer genomics, the genomics of heritable diseases, microbial and pathogen genomics, as well as novel sequencing and evolutionary genomics.

The American College of Surgeons Oncology Group is an NCI-funded cooperative group and is dedicated to conducting prospective therapeutic trials for breast, thoracic, and gastrointestinal cancers. As a surgeon-based multi-disciplinary cooperative group, ACOSOG is committed to translational research and tissue acquisition to advance our understanding of mechanisms of cancer response and resistance to systemic therapies.