BMC Medical Genomics (Apr 2019)
Sequencing and curation strategies for identifying candidate glioblastoma treatments
- Mayu O. Frank,
- Takahiko Koyama,
- Kahn Rhrissorrakrai,
- Nicolas Robine,
- Filippo Utro,
- Anne-Katrin Emde,
- Bo-Juen Chen,
- Kanika Arora,
- Minita Shah,
- Heather Geiger,
- Vanessa Felice,
- Esra Dikoglu,
- Sadia Rahman,
- Alice Fang,
- Vladimir Vacic,
- Ewa A. Bergmann,
- Julia L. Moore Vogel,
- Catherine Reeves,
- Depinder Khaira,
- Anthony Calabro,
- Duyang Kim,
- Michelle F. Lamendola-Essel,
- Cecilia Esteves,
- Phaedra Agius,
- Christian Stolte,
- John Boockvar,
- Alexis Demopoulos,
- Dimitris G. Placantonakis,
- John G. Golfinos,
- Cameron Brennan,
- Jeffrey Bruce,
- Andrew B. Lassman,
- Peter Canoll,
- Christian Grommes,
- Mariza Daras,
- Eli Diamond,
- Antonio Omuro,
- Elena Pentsova,
- Dana E. Orange,
- Stephen J. Harvey,
- Jerome B. Posner,
- Vanessa V. Michelini,
- Vaidehi Jobanputra,
- Michael C. Zody,
- John Kelly,
- Laxmi Parida,
- Kazimierz O. Wrzeszczynski,
- Ajay K. Royyuru,
- Robert B. Darnell
Affiliations
- Mayu O. Frank
- New York Genome Center
- Takahiko Koyama
- IBM Thomas J. Watson Research Center
- Kahn Rhrissorrakrai
- IBM Thomas J. Watson Research Center
- Nicolas Robine
- New York Genome Center
- Filippo Utro
- IBM Thomas J. Watson Research Center
- Anne-Katrin Emde
- New York Genome Center
- Bo-Juen Chen
- New York Genome Center
- Kanika Arora
- New York Genome Center
- Minita Shah
- New York Genome Center
- Heather Geiger
- New York Genome Center
- Vanessa Felice
- New York Genome Center
- Esra Dikoglu
- New York Genome Center
- Sadia Rahman
- New York Genome Center
- Alice Fang
- New York Genome Center
- Vladimir Vacic
- New York Genome Center
- Ewa A. Bergmann
- New York Genome Center
- Julia L. Moore Vogel
- New York Genome Center
- Catherine Reeves
- New York Genome Center
- Depinder Khaira
- New York Genome Center
- Anthony Calabro
- New York Genome Center
- Duyang Kim
- New York Genome Center
- Michelle F. Lamendola-Essel
- New York Genome Center
- Cecilia Esteves
- New York Genome Center
- Phaedra Agius
- New York Genome Center
- Christian Stolte
- New York Genome Center
- John Boockvar
- Northwell Health, Lenox Hill Hospital
- Alexis Demopoulos
- Northwell Health, The Brain Tumor Center
- Dimitris G. Placantonakis
- New York University, School of Medicine
- John G. Golfinos
- New York University, School of Medicine
- Cameron Brennan
- Memorial Sloan-Kettering Cancer Center
- Jeffrey Bruce
- Columbia University Medical Center
- Andrew B. Lassman
- Columbia University Medical Center
- Peter Canoll
- Columbia University Medical Center
- Christian Grommes
- Memorial Sloan-Kettering Cancer Center
- Mariza Daras
- Memorial Sloan-Kettering Cancer Center
- Eli Diamond
- Memorial Sloan-Kettering Cancer Center
- Antonio Omuro
- Memorial Sloan-Kettering Cancer Center
- Elena Pentsova
- Memorial Sloan-Kettering Cancer Center
- Dana E. Orange
- Laboratory of Molecular Neuro-Oncology, The Rockefeller University
- Stephen J. Harvey
- IBM Watson Health
- Jerome B. Posner
- Memorial Sloan-Kettering Cancer Center
- Vanessa V. Michelini
- IBM Watson Health
- Vaidehi Jobanputra
- New York Genome Center
- Michael C. Zody
- New York Genome Center
- John Kelly
- IBM Thomas J. Watson Research Center
- Laxmi Parida
- IBM Thomas J. Watson Research Center
- Kazimierz O. Wrzeszczynski
- New York Genome Center
- Ajay K. Royyuru
- IBM Thomas J. Watson Research Center
- Robert B. Darnell
- New York Genome Center
- DOI
- https://doi.org/10.1186/s12920-019-0500-0
- Journal volume & issue
-
Vol. 12,
no. 1
pp. 1 – 16
Abstract
Abstract Background Prompted by the revolution in high-throughput sequencing and its potential impact for treating cancer patients, we initiated a clinical research study to compare the ability of different sequencing assays and analysis methods to analyze glioblastoma tumors and generate real-time potential treatment options for physicians. Methods A consortium of seven institutions in New York City enrolled 30 patients with glioblastoma and performed tumor whole genome sequencing (WGS) and RNA sequencing (RNA-seq; collectively WGS/RNA-seq); 20 of these patients were also analyzed with independent targeted panel sequencing. We also compared results of expert manual annotations with those from an automated annotation system, Watson Genomic Analysis (WGA), to assess the reliability and time required to identify potentially relevant pharmacologic interventions. Results WGS/RNAseq identified more potentially actionable clinical results than targeted panels in 90% of cases, with an average of 16-fold more unique potentially actionable variants identified per individual; 84 clinically actionable calls were made using WGS/RNA-seq that were not identified by panels. Expert annotation and WGA had good agreement on identifying variants [mean sensitivity = 0.71, SD = 0.18 and positive predictive value (PPV) = 0.80, SD = 0.20] and drug targets when the same variants were called (mean sensitivity = 0.74, SD = 0.34 and PPV = 0.79, SD = 0.23) across patients. Clinicians used the information to modify their treatment plan 10% of the time. Conclusion These results present the first comprehensive comparison of technical and machine augmented analysis of targeted panel and WGS/RNA-seq to identify potential cancer treatments.
