In laboratory experiments, a metabolic inhibitor was able to kill a variety of human cancer cells of the skin, breast, lung, cervix and soft tissues through a non-apoptotic route — catastrophic macropinocytosis.
In mouse xenograft studies, the inhibitor acted synergistically with a common chemotherapy drug, cyclophosphamide, to reduce tumor growth. Thus macropinocytosis, a rarely described form of cell death, may aid in the treatment of cancer.
“Understanding the signaling pathways underlying macropinocytosis-associated cell death is an important step in developing additional effective strategies to treat neoplasms that are resistant to apoptosis induced by chemotherapy,” said Mohammad Athar, Ph.D., professor in the University of Alabama at Birmingham Department of Dermatology.
The inhibitor, OSI-027, affects the mTOR pathway, which plays a critical role in regulation cellular growth and metabolism. Significantly, this potent inhibitor simultaneously targets two distinct protein complexes of the mTOR pathway, mTORC1 and mTORC2. Aberrant activation of these components has been associated with many cancer types.
Macropinocytosis starts with formation of ruffles on the surface of a cell that reach out from the cell membrane. These ruffles then fuse back with the cell membrane, creating a bubble that holds extracellular fluid, and the bubble moves inside the cell to become a vacuole filled with fluid. In catastrophic micropinocytosis, large numbers of these vacuoles form inside the cell and then fuse together, causing cell death.
The UAB researchers showed that dual inhibition of the two mTORC1 and -C2 complexes was necessary for highly effective cell death through macropinocytosis.
In early experiments, the researchers found that OSI-027, and a related dual inhibitor, PP242, induced extensive vacuolization in a wide range of human cancer cell lines, including two subtypes of rhabdomyosarcoma. These vacuoles were then shown to be macropinosomes.
Xenograft mouse experiments with human rhabdomyosarcoma tumors showed that OSI-027 blocked tumor growth by inducing macropinocytosis; furthermore, the addition of the chemotherapy agent cyclophosphamide acted synergistically to enhance efficacy of tumor size reduction.
In mechanistic studies, Athar and colleagues found that macropinocytosis depended on activation of the MAP kinase MKK4, which was induced by the presence of reactive oxygen species. However, the full role of MKK4 is not well understood, they say.
Previous work by others had shown that several specific inducers of macropinocytosis induced macropinocytosis mainly in glioblastomas and colorectal cells. “In contrast,” Athar said, “our study demonstrates that the dual inhibitors we tested induce catastrophic vacuolization in tumor cell lines from a wide range of organs, including skin, breast, cervix, lung and soft tissues.”
The effects were much less pronounced in immortalized human keratinocytes.
“Our data reveal that therapeutic targeting of mTORC1 and mTORC2, together with standard care treatment,” Athar said, “may be an effective approach to block the pathogenesis of recurrent rhabdomyosarcoma and perhaps other drug-resistant invasive neoplasms of diverse tissue types as well. The underlying mechanism by which tumors become responsive to treatment involves macropinocytosis, a unique form of cell death.”
Co-authors with Athar of the study, “Combined mTORC1/mTORC2 inhibition blocks growth and induces catastrophic macropinocytosis in cancer cells,” published Proceedings of the National Academy of Sciences, are Ritesh K. Srivastava, Changzhao Li and Jasim Khan, UAB Department of Dermatology; and Louise T. Chow and Nilam Sanjib Banerjee, UAB Department of Biochemistry and Molecular Genetics.
Support came from National Institutes of Health grant ES026219 and funds from the Anderson Family Endowed Chair through UAB.
At UAB, Athar holds the Eric W. Baum, M.D., Endowed Professorship in Dermatology, and Chow holds the Anderson Family Chair in Medical Education, Research and Patient Care in the School of Medicine. Both are senior scientists in the O’Neal Comprehensive Cancer Center at UAB.