image: Human squamous carcinoma cells exhibit ATF2 (green) located at mitochondria (red) after exposure to genotoxic stress, whereas ATF2 remains in the nucleus in human melanoma cell exposed to the same genotoxic stress. Nuclei are shown in blue. view more
Credit: Ronai lab, Sanford-Burnham Medical Research Institute
LA JOLLA, Calif. -- The National Cancer Institute (NCI) estimates that as many as one in 51 men and women will be diagnosed with melanoma—the deadliest form of skin cancer—at some point during their lifetimes. A research team led by Ze'ev Ronai, Ph.D. at Sanford-Burnham Medical Research Institute (Sanford-Burnham) is working to unravel the molecular mechanisms underlying the development and progression of this disease in hopes of improving prevention and treatment strategies. To do this, Ronai's laboratory has been studying a protein named Activating Transcription Factor 2 (ATF2), which is associated with poor prognosis in melanoma. ATF2 is a two-faced protein—in melanoma cells, it's oncogenic, or cancer-causing, while in non-malignant types of skin cancers, it acts as a tumor suppressor. In a paper published February 3 in the journal Cell, the team identified a molecular switch that controls ATF2's dual functions. This switch is controlled by protein kinase Cε (PKCε), which disables ATF2's tumor-suppressing activities, sensitizing cells to chemotherapy; instead, ATF2's tumor-promoting activity is enhanced. The team also found that high levels of PKCε in melanoma are associated with poor prognosis.
"PKCε is the culprit behind melanoma's 'oncogenic addiction,'" said Ronai, associate director of the Sanford-Burnham's NCI-designated Cancer Center and senior author of the study. "ATF2 is normally a 'good guy.' But when there is too much PKCε—as in malignant melanoma—ATF2 becomes an oncogene, promoting tumor development."
In this study, Ronai and lead author Eric Lau, Ph.D., a postdoctoral researcher in his lab, found that PKCε's malignant power is in its ability to direct ATF2's location and activity within a cell. In a normal cell, PKCε modifies ATF2, keeping it in the nucleus, where it turns genes on and off and helps repair damaged DNA. When the cell experiences exposure to toxicity or stress (radiation, for example), PKCε backs off and ATF2 is able to move out of the nucleus and to the mitochondria, the part of the cell that generates energy and helps control cellular life and death. When it gets there, ATF2 helps to set the cell on a death course—a safeguard cells use to prevent errors that often make them cancerous.
PKCε levels are abnormally high in melanoma, and more PKCε means more ATF2 stuck in the nucleus, where it can't help the cells to die. Instead, in the nucleus, ATF2 promotes cellular survival and thus contributes to tumor development.
"We found that melanoma patients with high PKCε levels in their primary tumors were more likely to experience shorter survival times," said Lau. "This finding is consistent with earlier analyses of human melanoma tumors that showed a similar correlation between increased nuclear ATF2 and poor clinical outcome."
The Ronai laboratory, in collaboration with Sanford-Burnham's Conrad Prebys Center for Chemical Genomics, is currently searching for small molecules that help release ATF2 from PKCε's grip, thereby resuming ATF2's ability to promote cell death when needed. Since such an approach will effectively kill melanoma cells, it is expected to offer new therapeutic options for melanoma, and possibly other tumors with high PKCε levels.
"This work has clear potential for translation from a basic laboratory discovery to a melanoma therapy," said Michael Jackson, Ph.D., vice president of drug discovery and development at Sanford-Burnham. "We are excited to begin the screening process to identify a new class of drugs to treat cancer."
This study was funded by the National Cancer Institute (grants CA099961, CA051995, and CA121949) and the American Cancer Society, Illinois Division (fellowship PF-09-112-01-GMC). The study's co-authors include Eric Lau, Sanford-Burnham; Harriet Luger, Yale University; Tal Varsano, Sanford-Burnham; KiYoung Lee, University of California, San Diego and Ajou University; Immo Scheffler, University of California, San Diego; David Rimm, Yale University; Trey Ideker, University of California, San Diego; and Ze'ev A. Ronai, Sanford-Burnham.
About Sanford-Burnham Medical Research Institute
Sanford-Burnham Medical Research Institute is dedicated to discovering the fundamental molecular causes of disease and devising the innovative therapies of tomorrow. The Institute consistently ranks among the top five organizations worldwide for its scientific impact in the fields of biology and biochemistry (defined by citations per publication) and currently ranks third in the nation in NIH funding among all laboratory-based research institutes. Sanford-Burnham is a highly innovative organization, currently ranking second nationally among all organizations in capital efficiency of generating patents, defined by the number of patents issued per grant dollars awarded, according to government statistics.
Sanford-Burnham utilizes a unique, collaborative approach to medical research and has established major research programs in cancer, neurodegeneration, diabetes, and infectious, inflammatory, and childhood diseases. The Institute is especially known for its world-class capabilities in stem cell research and drug discovery technologies. Sanford-Burnham is a U.S.-based, non-profit public benefit corporation, with operations in San Diego (La Jolla), Santa Barbara, and Orlando (Lake Nona). For more information, please visit our website (http://www.sanfordburnham.org) or blog (http://beaker.sanfordburnham.org). You can also receive updates by following us on Facebook and Twitter.
Journal
Cell