BMC Cancer (Jun 2019)

Probabilistic modeling of personalized drug combinations from integrated chemical screen and molecular data in sarcoma

  • Noah E. Berlow,
  • Rishi Rikhi,
  • Mathew Geltzeiler,
  • Jinu Abraham,
  • Matthew N. Svalina,
  • Lara E. Davis,
  • Erin Wise,
  • Maria Mancini,
  • Jonathan Noujaim,
  • Atiya Mansoor,
  • Michael J. Quist,
  • Kevin L. Matlock,
  • Martin W. Goros,
  • Brian S. Hernandez,
  • Yee C. Doung,
  • Khin Thway,
  • Tomohide Tsukahara,
  • Jun Nishio,
  • Elaine T. Huang,
  • Susan Airhart,
  • Carol J. Bult,
  • Regina Gandour-Edwards,
  • Robert G. Maki,
  • Robin L. Jones,
  • Joel E. Michalek,
  • Milan Milovancev,
  • Souparno Ghosh,
  • Ranadip Pal,
  • Charles Keller

DOI
https://doi.org/10.1186/s12885-019-5681-6
Journal volume & issue
Vol. 19, no. 1
pp. 1 – 23

Abstract

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Abstract Background Cancer patients with advanced disease routinely exhaust available clinical regimens and lack actionable genomic medicine results, leaving a large patient population without effective treatments options when their disease inevitably progresses. To address the unmet clinical need for evidence-based therapy assignment when standard clinical approaches have failed, we have developed a probabilistic computational modeling approach which integrates molecular sequencing data with functional assay data to develop patient-specific combination cancer treatments. Methods Tissue taken from a murine model of alveolar rhabdomyosarcoma was used to perform single agent drug screening and DNA/RNA sequencing experiments; results integrated via our computational modeling approach identified a synergistic personalized two-drug combination. Cells derived from the primary murine tumor were allografted into mouse models and used to validate the personalized two-drug combination. Computational modeling of single agent drug screening and RNA sequencing of multiple heterogenous sites from a single patient’s epithelioid sarcoma identified a personalized two-drug combination effective across all tumor regions. The heterogeneity-consensus combination was validated in a xenograft model derived from the patient’s primary tumor. Cell cultures derived from human and canine undifferentiated pleomorphic sarcoma were assayed by drug screen; computational modeling identified a resistance-abrogating two-drug combination common to both cell cultures. This combination was validated in vitro via a cell regrowth assay. Results Our computational modeling approach addresses three major challenges in personalized cancer therapy: synergistic drug combination predictions (validated in vitro and in vivo in a genetically engineered murine cancer model), identification of unifying therapeutic targets to overcome intra-tumor heterogeneity (validated in vivo in a human cancer xenograft), and mitigation of cancer cell resistance and rewiring mechanisms (validated in vitro in a human and canine cancer model). Conclusions These proof-of-concept studies support the use of an integrative functional approach to personalized combination therapy prediction for the population of high-risk cancer patients lacking viable clinical options and without actionable DNA sequencing-based therapy.

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