Heba Alkhatib1, Ariel M Rubinstein1, Amichay Meirovitz2, Nataly Kravchenko-Balasha3, Swetha Vasudevan1, Efrat Flashner-Abramson1, Shira Stefansky1, Sangita Roy Chowdhury1, Solomon Oguche1, Tamar Peretz-Yablonsky4, Avital Granit4, Zvi Granot5, Ittai Ben-Porath5, Kim Sheva6, Jon Feldman4, Noa E Cohen7. 1. The institute of Biomedical and Oral Research, The Hebrew University of Jerusalem, 9103401, Jerusalem, Israel. 2. The Legacy Heritage Oncology Center & Dr. Larry Norton Institute, Soroka University Medical Center, Ben Gurion University of the Negev, Faculty of Medicine, 8410101, Beer Sheva, Israel. amichaym@gmail.com. 3. The institute of Biomedical and Oral Research, The Hebrew University of Jerusalem, 9103401, Jerusalem, Israel. natalyk@ekmd.huji.ac.il. 4. Sharett Institute of Oncology, Hebrew University-Hadassah Medical Center, 9103401, Jerusalem, Israel. 5. Department of Developmental Biology and Cancer Research, Institute for Medical Research-Israel-Canada, The Hebrew University-Hadassah Medical School, 91120, Jerusalem, Israel. 6. The Legacy Heritage Oncology Center & Dr. Larry Norton Institute, Soroka University Medical Center, Ben Gurion University of the Negev, Faculty of Medicine, 8410101, Beer Sheva, Israel. 7. School of Software Engineering and Computer Science, Azrieli College of Engineering, 9103501, Jerusalem, Israel.
Abstract
BACKGROUND: Drug resistance continues to be a major limiting factor across diverse anti-cancer therapies. Contributing to the complexity of this challenge is cancer plasticity, in which one cancer subtype switches to another in response to treatment, for example, triple-negative breast cancer (TNBC) to Her2-positive breast cancer. For optimal treatment outcomes, accurate tumor diagnosis and subsequent therapeutic decisions are vital. This study assessed a novel approach to characterize treatment-induced evolutionary changes of distinct tumor cell subpopulations to identify and therapeutically exploit anticancer drug resistance. METHODS: In this research, an information-theoretic single-cell quantification strategy was developed to provide a high-resolution and individualized assessment of tumor composition for a customized treatment approach. Briefly, this single-cell quantification strategy computes cell barcodes based on at least 100,000 tumor cells from each experiment and reveals a cell-specific signaling signature (CSSS) composed of a set of ongoing processes in each cell. RESULTS: Using these CSSS-based barcodes, distinct subpopulations evolving within the tumor in response to an outside influence, like anticancer treatments, were revealed and mapped. Barcodes were further applied to assign targeted drug combinations to each individual tumor to optimize tumor response to therapy. The strategy was validated using TNBC models and patient-derived tumors known to switch phenotypes in response to radiotherapy (RT). CONCLUSIONS: We show that a barcode-guided targeted drug cocktail significantly enhances tumor response to RT and prevents regrowth of once-resistant tumors. The strategy presented herein shows promise in preventing cancer treatment resistance, with significant applicability in clinical use.
BACKGROUND: Drug resistance continues to be a major limiting factor across diverse anti-cancer therapies. Contributing to the complexity of this challenge is cancer plasticity, in which one cancer subtype switches to another in response to treatment, for example, triple-negative breast cancer (TNBC) to Her2-positive breast cancer. For optimal treatment outcomes, accurate tumor diagnosis and subsequent therapeutic decisions are vital. This study assessed a novel approach to characterize treatment-induced evolutionary changes of distinct tumor cell subpopulations to identify and therapeutically exploit anticancer drug resistance. METHODS: In this research, an information-theoretic single-cell quantification strategy was developed to provide a high-resolution and individualized assessment of tumor composition for a customized treatment approach. Briefly, this single-cell quantification strategy computes cell barcodes based on at least 100,000 tumor cells from each experiment and reveals a cell-specific signaling signature (CSSS) composed of a set of ongoing processes in each cell. RESULTS: Using these CSSS-based barcodes, distinct subpopulations evolving within the tumor in response to an outside influence, like anticancer treatments, were revealed and mapped. Barcodes were further applied to assign targeted drug combinations to each individual tumor to optimize tumor response to therapy. The strategy was validated using TNBC models and patient-derived tumors known to switch phenotypes in response to radiotherapy (RT). CONCLUSIONS: We show that a barcode-guided targeted drug cocktail significantly enhances tumor response to RT and prevents regrowth of once-resistant tumors. The strategy presented herein shows promise in preventing cancer treatment resistance, with significant applicability in clinical use.
Authors: Hisani N Horne; Hannah Oh; Mark E Sherman; Maya Palakal; Stephen M Hewitt; Marjanka K Schmidt; Roger L Milne; David Hardisson; Javier Benitez; Carl Blomqvist; Manjeet K Bolla; Hermann Brenner; Jenny Chang-Claude; Renata Cora; Fergus J Couch; Katarina Cuk; Peter Devilee; Douglas F Easton; Diana M Eccles; Ursula Eilber; Jaana M Hartikainen; Päivi Heikkilä; Bernd Holleczek; Maartje J Hooning; Michael Jones; Renske Keeman; Arto Mannermaa; John W M Martens; Taru A Muranen; Heli Nevanlinna; Janet E Olson; Nick Orr; Jose I A Perez; Paul D P Pharoah; Kathryn J Ruddy; Kai-Uwe Saum; Minouk J Schoemaker; Caroline Seynaeve; Reijo Sironen; Vincent T H B M Smit; Anthony J Swerdlow; Maria Tengström; Abigail S Thomas; A Mieke Timmermans; Rob A E M Tollenaar; Melissa A Troester; Christi J van Asperen; Carolien H M van Deurzen; Flora F Van Leeuwen; Laura J Van't Veer; Montserrat García-Closas; Jonine D Figueroa Journal: Sci Rep Date: 2018-04-26 Impact factor: 4.379