The most deadly aspect of breast cancer is metastasis. It spreads cancer cells throughout the body. Researchers at the University and the University Hospital of Basel have now discovered a substance that suppresses the formation of metastases. The development of metastasis is responsible for more than 90% of cancer-related deaths, and patients with a metastatic disease are considered incurable. An interdisciplinary team from the Department of Biomedicine at the University of Basel has identified a drug that suppresses the spread of malignant cancer cells and their metastasis-seeding ability.
Precursors of metastases: Circulating tumor cell clusters
Circulating tumor cells (CTCs) are cancer cells that leave a primary tumor and enter the bloodstream, on their way to seeding distant metastases. These so-called CTCs can be found in the blood of patients as single cells or cell clusters. CTC clusters are the precursors of metastases. The Basel research team has discovered that CTC cluster formation leads to key epigenetic changes that facilitate metastasis seeding. These changes enable CTC clusters to mimic some properties of embryonic stem cells, including their ability to proliferate while retaining tissue-forming capabilities. The scientists have also shown that these epigenetic changes are fully reversible upon the dissociation of CTC clusters.
In their search for a substance that suppresses metastasis development, the research team tested 2486 FDA-approved compounds used for a number of different indications. They found inhibitors with the unexpected ability to dissociate patient-derived CTC clusters. This drug-based dissociation of CTC clusters into individual cells also resulted into epigenetic remodeling and prevented the formation of new metastases.
Preventing metastasis versus killing cancer cells
”We thought of acting differently from standard approaches, and sought to identify drugs that do not kill cancer cells, but simply dissociate them,” states Nicola Aceto, holder of an ERC starting grant and SNSF professorship.
In the fight against breast cancer, metastases remain the greatest danger. These new findings on the mechanisms of metastasis formation are the result of a large collaborative effort across various disciplines. “Our ambitious approach would not have been possible without collaboration with outstanding clinicians, molecular and computational biologists, with the support of state-of-the-art technology platforms,” says Aceto and adds: “Our methodology is positioned directly at the interface between these different disciplines. We are already working on the next step, which is to conduct a clinical trial with breast cancer patients.”
The accompanying image was chosen as cover story for the current issue of Cell. On our Sci Five blog , science photographer Martin Oeggerli reports on his collaboration with Nicola Aceto and Team.
Sofia Gkountela, Francesc Castro-Giner, Barbara Maria Szczerba, Marcus Vetter, Julia Landin, Ramona Scherrer, Ilona Krol, Manuel C. Scheidmann, Christian Beisel, Christian U. Stirnimann, Christian Kurzeder, Viola Heinzelmann-Schwarz, Christoph Rochlitz, Walter Paul Weber, Nicola Aceto
Circulating Tumor Cell Clustering Shapes DNA Methylation to Enable Metastasis Seeding
Cell (2018), doi: 10.1016/j.cell.2018.11.046