Abstract

Cancer diagnosis and treatment decisions have historically been based on anatomic sites of origin and spread;however, the emerging paradigm incorporates key genetic attributes of a given tumor to predict clinical behavior and specify the optimal use of targeted therapeutics. Ultimately, the delivery of personalized cancer medicine will require systematic characterization of all therapeutically informative tumor genomic alterations in the clinical and translational arena. Previously, we developed and deployed OncoMap, a mass spectrometric genotyping-based platform that enables high-throughput profiling of hundreds of known mutations across dozens of cancer genes. This platform performs well and has launched a robust translational oncology effort. However, the mass spectrometric genotyping technology remains limited in scope, assay sensitivity, and the type of genomic alteration that can be identified. Recently, it has become possible to render multi-faceted tumor characterization both technologically feasible and economically accessible through massively parallel sequencing (MPS) technology. Thus, the goal of this application is to migrate the OncoMap approach to an MPS platform (Illumina), empowered by innovations such as solution-phase exon capture and sample barcoding. Together with our colleagues at the Dana-Farber Cancer Institute and Broad Institute, we have generated preliminary data showing the feasibility and promise of each of these components, thereby raising the possibility of comprehensive tumor sequencing at a low per-sample cost. Accordingly, in this R33 application we will implement a transformative platform for systematic tumor genomic profiling, which we call """"""""MPS-OncoMap."""""""" To accomplish this we will optimize the methodology for sample barcoding technology, solution-phase exon capture, and single-molecule sequencing to enable robust mutation profiling (base mutations, amplifications, and deletions) across ~150 cancer genes in at least 12 tumor samples simultaneously. We will test the performance of MPS-OncoMap using DNA from cancer cell lines, frozen tumors, and formalin-fixed, paraffin-embedded tumor tissue for which the """"""""ground truth"""""""" is known for multiple genetic alterations. Finally, we will implement MPS-OncoMap at production scale to enable systematic analyses for many translational oncology applications. Achieving these Aims may inform a definitive path to comprehensive tumor genomic profiling with far-reaching impact in the translational and clinical oncology arena.

Public Health Relevance

High-Throughput Cancer Gene Mutation Profiling y Massively Parallel Sequencing PIs: Levi A. Garraway, M.D., Ph.D. and Laura E. MacConaill, Ph.D. Many cancers are caused by mutations in the DNA that give rise to altered proteins or cellular processes. The use of anticancer drugs targeting such proteins can lead to significant clinical benefit, but it remains impractical to profile the tumor of each cancer patient for the presence of such alterations. This application seeks to adapt a powerful new sequencing technology together with other innovations to make it possible to detect many informative cancer gene mutations in clinical tumor specimens. Once implemented, this approach could speed the advent of personalized cancer medicine.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Exploratory/Developmental Grants Phase II (R33)
Project #
5R33CA155554-02
Application #
8335409
Study Section
Special Emphasis Panel (ZCA1-SRLB-R (O1))
Program Officer
Sorg, Brian S
Project Start
2011-09-20
Project End
2014-08-31
Budget Start
2012-09-01
Budget End
2013-08-31
Support Year
2
Fiscal Year
2012
Total Cost
$263,445
Indirect Cost
$112,905

  Institution

Name
Dana-Farber Cancer Institute
Department
Type
DUNS #
076580745
City
Boston
State
MA
Country
United States
Zip Code
02215

  Publications

Whittaker, Steven R; Cowley, Glenn S; Wagner, Steve et al. (2015) Combined Pan-RAF and MEK Inhibition Overcomes Multiple Resistance Mechanisms to Selective RAF Inhibitors. Mol Cancer Ther 14:2700-11
Wilson, Frederick H; Johannessen, Cory M; Piccioni, Federica et al. (2015) A functional landscape of resistance to ALK inhibition in lung cancer. Cancer Cell 27:397-408
Wagle, Nikhil; Grabiner, Brian C; Van Allen, Eliezer M et al. (2014) Response and acquired resistance to everolimus in anaplastic thyroid cancer. N Engl J Med 371:1426-33
MacConaill, Laura E; Garcia, Elizabeth; Shivdasani, Priyanka et al. (2014) Prospective enterprise-level molecular genotyping of a cohort of cancer patients. J Mol Diagn 16:660-72
Van Allen, Eliezer M; Wagle, Nikhil; Sucker, Antje et al. (2014) The genetic landscape of clinical resistance to RAF inhibition in metastatic melanoma. Cancer Discov 4:94-109
Wagle, Nikhil; Van Allen, Eliezer M; Treacy, Daniel J et al. (2014) MAP kinase pathway alterations in BRAF-mutant melanoma patients with acquired resistance to combined RAF/MEK inhibition. Cancer Discov 4:61-8
Van Allen, Eliezer M; Wagle, Nikhil; Stojanov, Petar et al. (2014) Whole-exome sequencing and clinical interpretation of formalin-fixed, paraffin-embedded tumor samples to guide precision cancer medicine. Nat Med 20:682-8
MacConaill, Laura E (2013) Existing and emerging technologies for tumor genomic profiling. J Clin Oncol 31:1815-24
Johannessen, Cory M; Johnson, Laura A; Piccioni, Federica et al. (2013) A melanocyte lineage program confers resistance to MAP kinase pathway inhibition. Nature 504:138-42
Baca, Sylvan C; Prandi, Davide; Lawrence, Michael S et al. (2013) Punctuated evolution of prostate cancer genomes. Cell 153:666-77

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