Study charts “genomic biography” of form of leukemia

A new study by scientists at Dana-Farber Cancer Institute and the Broad Institute of MIT and Harvard offers a glimpse of the wealth of information that can be gleaned by combing the genome of a large collection of leukemia tissue samples.

By analyzing genetic material in chronic lymphocytic leukemia (CLL) and normal tissue from more than 500 patients, researchers identified dozens of genetic abnormalities that may drive the disease, including two that had never before been linked to human cancer. They began to trace how some of these abnormalities affect the course of the disease and its susceptibility to treatment. And they started tracking the evolutionary path of CLL, as its ever-churning genome spawns new groups and subgroups of tumor cells in a single patient.

This type of information is critical as the treatment of CLL is increasingly geared to the unique genetic features of each patient’s tumor. Traditional chemotherapy regimens are now being supplemented by drugs that target the specific set of delinquent genes within cancer cells.

“Sequencing the DNA of CLL has taught us a great deal about the genetic basis of the disease,” said Catherine Wu, MD, of Dana-Farber, the Broad Institute of MIT and Harvard, and Brigham and Women’s Hospital, a senior author of the study, which is being published today by the journal Nature. “Previous studies, however, were limited by the relatively small number of tumor tissue samples analyzed, and by the fact that those samples were taken at different stages of the treatment process, from patients treated with different drug agents.

“In our new study, we wanted to determine if analyzing tissue samples from a large, similarly-treated group of patients provides the statistical power necessary to study the disease in all its genetic diversity – to draw connections between certain mutations and the aggressiveness of the disease, and to chart the emergence of new mutations and their role in helping the disease advance,” she continued. “Our results demonstrate the range of insights to be gained by this approach.”

“This study also provides a vision of what the next phase of large scale genomic sequencing efforts may look like,” said Dan Landau MD, PhD, of Dana-Farber, the Broad Institute of MIT and Harvard, and Brigham and Women’s Hospital, a first author of the study. “The growing sample size allows us to start engaging deeply with the complex interplay between different mutations found in any individual tumor, as well as reconstructs the evolutionary trajectories in which these mutations are acquired to allow the malignancy to thrive and overcome therapy.”

Wu and her team collected tumor and normal tissue samples from 538 patients with CLL, 278 of whom had participated in a German clinical trial that helped determine the standard treatment for the disease. They performed whole-exome sequencing (WES) on each sample, reading the genetic code letter by letter in sections of DNA that hold the code for making proteins. An analysis of the data yielded a broad range of insights:

• Researchers identified dozens of genetic abnormalities that may play a role in CLL, including 44 mutated genes and 11 genes that were over- or under-copied in CLL cells. Two of the mutated genes – RPS15 and IKZF3 – have not previously been associated with human cancer.
• Nearly 9 percent of the patients had mutations in the MAPK-ERK pathway, a network of proteins that relay growth signals. In some patients, researchers identified new types of molecular errors that allow the MYC cancer gene to become overactive.
• Many of the mutations found in the BRAF gene occurred near, but not at, the spot most commonly involved in other cancers.
• Certain gene mutations were found to be especially common in tumor tissue from patients who had already undergone treatment, suggesting that these mutations help the disease rebound after initial therapy.
• Researchers compiled a rough draft of a “molecular biography” of CLL by determining which mutations tend to arise early or late in the course of the disease. They also identified mutations that often occur in pairs, one followed by the other.
• The investigators found that therapy tends to produce shorter remissions in patients whose tumors carry mutations in the genes TP53 or SF3B1.
• By comparing tumor samples collected prior to treatment and after relapse, “we found that genomic evolution after therapy is the rule rather than the exception,” Wu remarked. “Certain mutations were present in a greater number of leukemia cells within a sample after relapse, showing that these mutations, presumably, allow the tumor to persevere.” Wu and her colleagues observed three general patterns in these shifting mutations.

“The breadth of our findings shows what we will be able to achieve as we systematically sequence and analyze large cohorts of tumor tissue samples with defined clinical status,” remarked Gad Getz, PhD, of the Broad Institute and Massachusetts General Hospital, co-senior author of the paper. “Our work has enabled us to discover novel cancer genes, begin to chart the evolutionary path of CLL, and demonstrate specific mutations affect patients’ response to therapy. These discoveries will form the basis for precision medicine of CLL and other tumor types.”

The other co-senior authors of the paper are Stephan Stilgenbauer, MD, of Ulm University, Ulm, Germany, Michael Hallek, MD, of University Hospital, Cologne, Germany, the German CLL Study Group, and Cologne Cluster of Excellence in Cellular Stress Responses in Aging-associated Diseases, and Donna Neuberg, ScD, of Dana-Farber. The other co-first authors are Eugen Tausch, MD, of Ulm University, and Amaro Taylor-Weiner of Dana-Farber. Co-authors are: Chip Stewart, Mike Lawrence, Kristian Cibulskis, Carrie Sougnez, Mara Rosenberg, Julian Hess, Stacey Gabriel, and Eric Lander, PhD, of the Broad Institute; Scott Carter, PhD, of Dana-Farber and the Broad; Johannes Reiter of Dana-Farber, the Broad, and the Institute of Science and Technology Austria, and Harvard University; Jasmin Bahlo, and Sandra Kluth of University Hospital, Cologne, Germany, and Harvard University; Ivana Bozic, PhD, and Martin Nowak of Harvard University; Sebastian Böttcher, MD, Michael Kneba, MD, and Matthias Ritgen, MD, of University Hospital of Schleswig-Holstein, Kiel, Germany; Daniel Mertens, PhD, of German Cancer Research Center, Heidelberg, Germany; Jennifer Edelmann, MD, Sabrina Kless, and Hartmut Döhner, MD, of Ulm University; Anna Fink, MD, and Kirsten Fischer, MD, of University Hospital, Cologne, Germany, and the German CLL Study Group.

Funding for the study was provided by the National Institutes of Health (grants 1K01ES025431-01, 1R01CA182461-02, 1R01CA184922-01), the European Research Council (start grant 279307), the Austrian Science Fund (grants P23499-N23, S11407-N23), the American Cancer Society, the American Society of Hematology, the Burroughs Wellcome Fund Career Award for Medical Scientists, German Jose Carreras Leukemia Foundation (project R 06/03v), the Deutsche Forschungsgemeinschaft (KFO 286, Project 6), the Else Kröner-Fresenius-Stiftung (2010_Kolleg24, 2012_A146), Virtual Helmholtz Institute (VH-VI-404), CLL Global Research Foundation (Alliance), and Deutsche Forschungsgemeinschaft (SFB 1074 projects B1, B2), the Blavatnik Family Foundation, and the American Association for Cancer Research (SU2C Innovative Research Grant).

About Dana-Farber Cancer Institute
Dana-Farber Cancer Institute, a principal teaching affiliate of Harvard Medical School, is world-renowned for its leadership in adult and pediatric cancer treatment and research. Designated as a comprehensive cancer center by the National Cancer Institute (NCI), it is one of the largest recipients among independent hospitals of NCI and National Institutes of Health grant funding. For more information, go to

About the Broad Institute of MIT and Harvard
The Eli and Edythe L. Broad Institute of MIT and Harvard was launched in 2004 to empower this generation of creative scientists to transform medicine. The Broad Institute seeks to describe all the molecular components of life and their connections; discover the molecular basis of major human diseases; develop effective new approaches to diagnostics and therapeutics; and disseminate discoveries, tools, methods and data openly to the entire scientific community.

Founded by MIT, Harvard and its affiliated hospitals, and the visionary Los Angeles philanthropists Eli and Edythe L. Broad, the Broad Institute includes faculty, professional staff and students from throughout the MIT and Harvard biomedical research communities and beyond, with collaborations spanning over a hundred private and public institutions in more than 40 countries worldwide. For further information about the Broad Institute, go to