Study reveals a way to make prostate cancer cells run out of energy and die
Cold Spring Harbor, NY – Scientists at Cold Spring Harbor Laboratory (CSHL) have discovered that cells lacking the tumor-suppressor protein PTEN–a feature of many cancers– are particularly vulnerable to drugs that impair their energy-producing mitochondria. Such drugs induce them to literally eat themselves to death, the research shows.
Unlike normal cells, cells without PTEN seem driven to preserve their mitochondria at all costs, says the team leader, CSHL Professor Lloyd Trotman. He and colleagues have found that when such cells are treated with certain mitochondrial inhibitors, they consume vast quantities of glucose to fuel these efforts. As a result, they quickly run out of energy and die.
Some mitochondrial inhibitors, including the widely prescribed diabetes medication metformin – one of the most widely taken drugs in the world — are already being evaluated in clinical trials for their ability to prevent or treat many types of cancer.
The new findings, reported today in Cell Reports, suggest that such drugs have the potential to eliminate cancer cells at doses that leave healthy cells intact. The timing is critical, however. When glucose levels are high, this window of opportunity is completely lost. "The hope is that carefully timed administration of these drugs can generate a much better window of selective killing," Trotman says.
Two related compounds, both derived from the root of the same plant, emerged from a screen performed by the team. Both killed cells missing PTEN and another tumor suppressor, p53. Loss of these together is common among men with advanced prostate cancer and is associated with highly metastatic disease.
The two drugs had little effect on nearly identical cells with functional PTEN. One, rotenone, is a known mitochondrial inhibitor. In collaboration with Navdeep Chandel at Northwestern University, Trotman's lab established that the second compound, deguelin, works in much the same way.
Oddly, further experiments with deguelin revealed that it shuts down mitochondrial function just as well in cells with PTEN as it does in cells that lack it. So why did cells with PTEN tolerate the toxic compound so much better?
The answer has to do with how cells use glucose, say co-first authors of the paper, postdoctoral researchers Adam Naguib and Grinu Mathew. They found that cells without PTEN use glucose from their environment to generate the energy-rich molecule ATP, which they import into mitochondria to keep them intact. "That's the exact opposite of what mitochondria are supposed to be doing," Trotman points out. "Mitochondria are supposed to generate ATP for the rest of the cell." For these cells lacking PTEN, unless there is an endless supply of glucose, they quickly use up the sugar and die.
Eventually, any cell subjected to mitochondrial inhibitors will run out of energy and die. Cells without PTEN just get there much faster, Trotman says. That means it could be critical to administer mitochondrial inhibitors to cancer patients when their blood sugar is low, he says. That's counter to how metformin and related medications are currently tested in cancer, because the protocol used to manage diabetes calls for the drugs to be taken immediately after meals.
Funding: American Cancer Society, Pershing Square Sohn Foundation, U.S. Department of Defense, National Institutes of Health, American Cancer Society, Robertson Research Fund of CSHL, CSHL Cancer Center Support Grant from the NIH.
Citation: Naguib A. et al, "Mitochondrial complex I inhibitors expose a vulnerability for selective killing of Pten-null cells" appears online in Cell Reports April 3, 2018.
About Cold Spring Harbor Laboratory
Founded in 1890, Cold Spring Harbor Laboratory has shaped contemporary biomedical research and education with programs in cancer, neuroscience, plant biology and quantitative biology. Home to eight Nobel Prize winners, the private, not-for-profit Laboratory employs 1,100 people including 600 scientists, students and technicians. The Meetings & Courses Program annually hosts more than 12,000 scientists. The Laboratory's education arm also includes an academic publishing house, a graduate school and the DNA Learning Center with programs for middle and high school students and teachers. For more information, visit http://www.cshl.edu