Your search keyword '"Jack F. Shern"' showing total 167 results

1. Circulating Tumor DNA Is Prognostic in Intermediate-Risk Rhabdomyosarcoma: A Report From the Children's Oncology Group

Author

Samuel Abbou, Kelly Klega, Junko Tsuji, Mohammad Tanhaemami, David Hall, Donald A. Barkauskas, Mark D. Krailo, Carrie Cibulskis, Anwesha Nag, Aaron R. Thorner, Samuel Pollock, Alma Imamovic-Tuco, Jack F. Shern, Steven G. DuBois, Rajkumar Venkatramani, Douglas S. Hawkins, and Brian D. Crompton

Subjects

Cancer Research, Oncology

Abstract

PURPOSE Novel biomarkers are needed to differentiate outcomes in intermediate-risk rhabdomyosarcoma (IR RMS). We sought to evaluate strategies for identifying circulating tumor DNA (ctDNA) in IR RMS and to determine whether ctDNA detection before therapy is associated with outcome. PATIENTS AND METHODS Pretreatment serum and tumor samples were available from 124 patients with newly diagnosed IR RMS from the Children's Oncology Group biorepository, including 75 patients with fusion-negative rhabdomyosarcoma (FN-RMS) and 49 with fusion-positive rhabdomyosarcoma (FP-RMS) disease. We used ultralow passage whole-genome sequencing to detect copy number alterations and a new custom sequencing assay, Rhabdo-Seq, to detect rearrangements and single-nucleotide variants. RESULTS We found that ultralow passage whole-genome sequencing was a method applicable to ctDNA detection in all patients with FN-RMS and that ctDNA was detectable in 13 of 75 serum samples (17%). However, the use of Rhabdo-Seq in FN-RMS samples also identified single-nucleotide variants, such as MYOD1 L122R, previously associated with prognosis. Identification of pathognomonic translocations between PAX3 or PAX7 and FOXO1 by Rhabdo-Seq was the best method for measuring ctDNA in FP-RMS and detected ctDNA in 27 of 49 cases (55%). Patients with FN-RMS with detectable ctDNA at diagnosis had significantly worse outcomes than patients without detectable ctDNA (event-free survival, 33.3% v 68.9%; P = .0028; overall survival, 33.3% v 83.2%; P < .0001) as did patients with FP-RMS (event-free survival, 37% v 70%; P = .045; overall survival, 39.2% v 75%; P = .023). In multivariable analysis, ctDNA was independently associated with worse prognosis in FN-RMS but not in the smaller FP-RMS cohort. CONCLUSION Our study demonstrates that baseline ctDNA detection is feasible and is prognostic in IR RMS.

Published

2023

2. The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Katie E. Hebron, Xiaolin Wan, Jacob S. Roth, David J. Liewehr, Nancy E. Sealover, William J.E. Frye, Angela Kim, Stacey Stauffer, Olivia L. Perkins, Wenyue Sun, Kristine A. Isanogle, Christina M. Robinson, Amy James, Parirokh Awasthi, Priya Shankarappa, Xiaoling Luo, Haiyan Lei, Donna Butcher, Roberta Smith, Elijah F. Edmondson, Jin-Qiu Chen, Noemi Kedei, Cody J. Peer, Jack F. Shern, W. Douglas Figg, Lu Chen, Matthew D. Hall, Simone Difilippantonio, Frederic G. Barr, Robert L. Kortum, Robert W. Robey, Angelina V. Vaseva, Javed Khan, and Marielle E. Yohe

Subjects

Cancer Research, Oncology

Abstract

Purpose: PAX-fusion negative rhabdomyosarcoma (FN RMS) is driven by alterations in the RAS/MAP kinase pathway and is partially responsive to MEK inhibition. Overexpression of IGF1R and its ligands is also observed in FN RMS. Preclinical and clinical studies have suggested that IGF1R is itself an important target in FN RMS. Our previous studies revealed preclinical efficacy of the MEK1/2 inhibitor, trametinib, and an IGF1R inhibitor, BMS-754807, but this combination was not pursued clinically due to intolerability in preclinical murine models. Here, we sought to identify a combination of an MEK1/2 inhibitor and IGF1R inhibitor, which would be tolerated in murine models and effective in both cell line and patient-derived xenograft models of RAS-mutant FN RMS. Experimental Design: Using proliferation and apoptosis assays, we studied the factorial effects of trametinib and ganitumab (AMG 479), a mAb with specificity for human and murine IGF1R, in a panel of RAS-mutant FN RMS cell lines. The molecular mechanism of the observed synergy was determined using conventional and capillary immunoassays. The efficacy and tolerability of trametinib/ganitumab was assessed using a panel of RAS-mutated cell-line and patient-derived RMS xenograft models. Results: Treatment with trametinib and ganitumab resulted in synergistic cellular growth inhibition in all cell lines tested and inhibition of tumor growth in four of six models of RAS-mutant RMS. The combination had little effect on body weight and did not produce thrombocytopenia, neutropenia, or hyperinsulinemia in tumor-bearing SCID beige mice. Mechanistically, ganitumab treatment prevented the phosphorylation of AKT induced by MEK inhibition alone. Therapeutic response to the combination was observed in models without a mutation in the PI3K/PTEN axis. Conclusions: We demonstrate that combined trametinib and ganitumab is effective in a genomically diverse panel of RAS-mutated FN RMS preclinical models. Our data also show that the trametinib/ganitumab combination likely has a favorable tolerability profile. These data support testing this combination in a phase I/II clinical trial for pediatric patients with relapsed or refractory RAS-mutated FN RMS.

Published

2022

3. Anti-GD2 Antibodies Conjugated to IL15 and IL21 Mediate Potent Antitumor Cytotoxicity against Neuroblastoma

Author

Rosa Nguyen, Xiyuan Zhang, Ming Sun, Shahroze Abbas, Charlie Seibert, Michael C. Kelly, Jack F. Shern, and Carol J. Thiele

Subjects

Interleukin-15, Mice, Neuroblastoma, Cancer Research, Oncology, Interleukins, Tumor Microenvironment, Animals, Humans, Interleukin-2, Mice, Nude, Article

Abstract

Purpose:Half of the patients with high-risk neuroblastoma who receive GD2-targeted mAb do not achieve long-term remissions. Recently, the antibody hu14.18 has been linked to IL2 (hu14.18-IL2) to enhance its efficacy and shown promising preclinical and clinical activity. We developed two new immunocytokines (IC) by linking two other γc cytokines, IL15 and IL21, to hu14.18. The purpose of this study was to compare hu14.18-IL15 and -IL21 with hu14.18-IL2 in their ability to induce antibody-dependent cell-mediated cytotoxicity (ADCC) against neuroblastoma.Experimental Design:We assessed ADCC of hu14.18-IL15 and -IL2 (human cytokines, cross-reactive to mouse) against GD2low and GD2high neuroblastoma cell lines in vitro. T-cell–deficient mice with orthotopic patient-derived xenografts (PDX) and immunocompetent mice with transplantable orthotopic neuroblastoma were used to test all three ICs, including hu14.18-IL21 (murine IL21, not cross-reactive to human). Mechanistic studies were performed using single-cell RNA-sequencing (scRNA-seq).Results:hu14.18-IL15 and hu14.18-IL2 mediated equivalent in vitro ADCC by human NK cells. When combined with chemotherapy, all three ICs similarly controlled the growth of PDXs in nude mice with murine NK effector cells. However, hu14.18-IL15 and -IL21 outperformed hu14.18-IL2 in immunocompetent mice with syngeneic neuroblastoma, inducing complete tumor regressions and extending survival. scRNA-seq data revealed an increase in CD8+ T cells and M1 tumor-associated macrophages and decreased regulatory T cells and myeloid-derived suppressor cells in the tumor microenvironment.Conclusions:Hu14.18-IL15 and Hu14.18-IL21 exhibit robust preclinical activity, warranting further consideration for clinical testing in patients with GD2-expressing neuroblastoma.

Published

2022

4. Supplementary Figure S7 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 186K, Loss of heterozygosity on Chromosome 11p15.5

Published

2023

5. Supplementary Figure S8 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 250K, Recurrent amplicons

Published

2023

6. Supplementary Figure S4 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 671K, BCOR alterations

Published

2023

7. Supplementary Figure S5 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 277K, Expressed mutations summary

Published

2023

8. Supplementary Legends from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 92K, Supplementary Legends

Published

2023

9. Supplementary Figure S6 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 145K, Recurrent Recurrence peaks of focal copy number change

Published

2023

10. Supplementary Figure S1 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 1441K, Genetic Lesions associated with "Fusion Negative" Alveolar cases

Published

2023

11. Supplementary Figure S10 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 1175K, Determination of a somatic score cutoff for WGS based on the verification by WES

Published

2023

12. Supplemental Methods and Legends from PAX3–FOXO1 Establishes Myogenic Super Enhancers and Confers BET Bromodomain Vulnerability

Author

Javed Khan, Craig J. Thomas, Keji Zhao, Jack F. Shern, Marc Ferrer, Madhu Lal-Nag, Rajarshi Guha, Thorkell Andresson, Sudipto Das, Frederic G. Barr, Jun S. Wei, Sivasish Sindiri, Xinyu Wen, Abigail Cleveland, Rossella Rota, Silvia Pomella, Alberto Gualtieri, Young Song, Nirmalya Sen, Beat Schaefer, Marco Wachtel, Joana Marques, Xiaohu Zhang, Hsien-Chao Chou, Marielle E. Yohe, and Berkley E. Gryder

Abstract

Supplemental Methods and Legends

Published

2023

13. Supplementary Figure S9 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 258K, Genome wide copy number profile.

Published

2023

14. Supplementary Tables S1-S10 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

XLSX file 2844K, Supplementary Tables S1-S10

Published

2023

15. Supplementary Figure S11 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 1261K, Reverse Transcription PCR of PAX3-FOXO1 in cell line 7250_PF

Published

2023

16. Supplementary Figure S2 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 1573K, Loss of heterozygosity across RMS tumor samples.

Published

2023

17. Supplementary Figure S3 from Comprehensive Genomic Analysis of Rhabdomyosarcoma Reveals a Landscape of Alterations Affecting a Common Genetic Axis in Fusion-Positive and Fusion-Negative Tumors

Author

Javed Khan, Douglas S. Hawkins, Matthew Meyerson, Frederic G. Barr, Stephen X. Skapek, James R. Anderson, Jaume Mora, Gad Getz, Thomas Badgett, Daniel Catchpoole, Sivasish Sindiri, Andrew S. Brohl, Dominik Bogen, Shile Zhang, Hongling Liao, Laura Hurd, Catherine Tolman, Young K. Song, Jianjun Wang, Daniel Auclair, Lauren Ambrogio, Mara Rosenberg, Rajesh Patidar, Jun S. Wei, Juliann Chmielecki, Li Chen, and Jack F. Shern

Abstract

PDF file 3294K, Germline alteration of TP53 in patient RMS212

Published

2023

18. Supplemental Tables from PAX3–FOXO1 Establishes Myogenic Super Enhancers and Confers BET Bromodomain Vulnerability

Author

Javed Khan, Craig J. Thomas, Keji Zhao, Jack F. Shern, Marc Ferrer, Madhu Lal-Nag, Rajarshi Guha, Thorkell Andresson, Sudipto Das, Frederic G. Barr, Jun S. Wei, Sivasish Sindiri, Xinyu Wen, Abigail Cleveland, Rossella Rota, Silvia Pomella, Alberto Gualtieri, Young Song, Nirmalya Sen, Beat Schaefer, Marco Wachtel, Joana Marques, Xiaohu Zhang, Hsien-Chao Chou, Marielle E. Yohe, and Berkley E. Gryder

Abstract

Supplemental Tables

Published

2023

19. Supplemental Figures 1 through 10 from PAX3–FOXO1 Establishes Myogenic Super Enhancers and Confers BET Bromodomain Vulnerability

Author

Javed Khan, Craig J. Thomas, Keji Zhao, Jack F. Shern, Marc Ferrer, Madhu Lal-Nag, Rajarshi Guha, Thorkell Andresson, Sudipto Das, Frederic G. Barr, Jun S. Wei, Sivasish Sindiri, Xinyu Wen, Abigail Cleveland, Rossella Rota, Silvia Pomella, Alberto Gualtieri, Young Song, Nirmalya Sen, Beat Schaefer, Marco Wachtel, Joana Marques, Xiaohu Zhang, Hsien-Chao Chou, Marielle E. Yohe, and Berkley E. Gryder

Abstract

Supplemental Figure 1. PAX3 Fusion in enhancer chromatin states. Supplemental Figure 2. Integration of Topological Domain Boundaries and RNA Expression Datasets Enable Discovery of Novel PAX3-FOXO1 Target Genes. Supplemental Figure 3. MYC and MYCN Expression, Enhancers and Super Enhancers in RMS Cell Lines and Primary Tumors, compared to Normal Skeletal Muscle and Myogenic Samples. Supplemental Figure 4. Genome-wide binding of PAX3-FOXO1, MYOD, MYOG and MYCN and their Functional Interdependence. Supplemental Figure 5. BRD4 at PAX3-FOXO1 Enhancers Predicts Presence of Looping Machinery and Increased Gene Expression. Supplemental Figure 6. Molecular Sensitivity Landscape of PAX3-FOXO1 RMS cells. Supplemental Figure 7. JQ1 potency across RMS cell lines and xenograft cultures. Supplemental Figure 8. Depletion of BET bromodomains in FP-RMS. Supplemental Figure 9. Impact of JQ1 on PAX3-FOXO1 target genes and PAX3-FOXO1 stability. Supplemental Figure 10. Validation of PAX3-FOXO1 Driven ALK SE Luciferase Contruct and In Vivo Efficacy of JQ1.

Published

2023

20. Supplementary Figure S3 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Pharmacodynamic response to trametinib/ganitumab in xenograft models does not predict tumor shrinkage

Published

2023

21. Data from Predicting Molecular Subtype and Survival of Rhabdomyosarcoma Patients Using Deep Learning of H&E Images: A Report from the Children's Oncology Group

Author

Javed Khan, Jack Collins, Jack F. Shern, Douglas S. Hawkins, Igor B. Kuznetsov, George Zaki, Seth M. Steinberg, Peter K. Bode, Rajkumar Venkatramani, Stephen X. Skapek, Hsien-Chao Chou, Jun S. Wei, Corinne M. Linardic, David Hall, Tammy Lo, Donald A. Barkauskas, Hyoyoung Choo-Wosoba, Erin R. Rudzinski, Marc Ladanyi, Curtis Lisle, Ben Somerville, Yanling Liu, G. Thomas Brown, Hyun Jung, and David Milewski

Abstract

Purpose:Rhabdomyosarcoma (RMS) is an aggressive soft-tissue sarcoma, which primarily occurs in children and young adults. We previously reported specific genomic alterations in RMS, which strongly correlated with survival; however, predicting these mutations or high-risk disease at diagnosis remains a significant challenge. In this study, we utilized convolutional neural networks (CNN) to learn histologic features associated with driver mutations and outcome using hematoxylin and eosin (H&E) images of RMS.Experimental Design:Digital whole slide H&E images were collected from clinically annotated diagnostic tumor samples from 321 patients with RMS enrolled in Children's Oncology Group (COG) trials (1998–2017). Patches were extracted and fed into deep learning CNNs to learn features associated with mutations and relative event-free survival risk. The performance of the trained models was evaluated against independent test sample data (n = 136) or holdout test data.Results:The trained CNN could accurately classify alveolar RMS, a high-risk subtype associated with PAX3/7-FOXO1 fusion genes, with an ROC of 0.85 on an independent test dataset. CNN models trained on mutationally-annotated samples identified tumors with RAS pathway with a ROC of 0.67, and high-risk mutations in MYOD1 or TP53 with a ROC of 0.97 and 0.63, respectively. Remarkably, CNN models were superior in predicting event-free and overall survival compared with current molecular-clinical risk stratification.Conclusions:This study demonstrates that high-risk features, including those associated with certain mutations, can be readily identified at diagnosis using deep learning. CNNs are a powerful tool for diagnostic and prognostic prediction of rhabdomyosarcoma, which will be tested in prospective COG clinical trials.

Published

2023

22. Figure S2 from Predicting Molecular Subtype and Survival of Rhabdomyosarcoma Patients Using Deep Learning of H&E Images: A Report from the Children's Oncology Group

Author

Javed Khan, Jack Collins, Jack F. Shern, Douglas S. Hawkins, Igor B. Kuznetsov, George Zaki, Seth M. Steinberg, Peter K. Bode, Rajkumar Venkatramani, Stephen X. Skapek, Hsien-Chao Chou, Jun S. Wei, Corinne M. Linardic, David Hall, Tammy Lo, Donald A. Barkauskas, Hyoyoung Choo-Wosoba, Erin R. Rudzinski, Marc Ladanyi, Curtis Lisle, Ben Somerville, Yanling Liu, G. Thomas Brown, Hyun Jung, and David Milewski

Abstract

Supplemental Figure S2. Sample partitioning for training and testing a TP53 mutation predictive model using K-fold cross-validation.

Published

2023

23. Supplementary Data File S9 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Related to Figure 4

Published

2023

24. Data from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Purpose:PAX-fusion negative rhabdomyosarcoma (FN RMS) is driven by alterations in the RAS/MAP kinase pathway and is partially responsive to MEK inhibition. Overexpression of IGF1R and its ligands is also observed in FN RMS. Preclinical and clinical studies have suggested that IGF1R is itself an important target in FN RMS. Our previous studies revealed preclinical efficacy of the MEK1/2 inhibitor, trametinib, and an IGF1R inhibitor, BMS-754807, but this combination was not pursued clinically due to intolerability in preclinical murine models. Here, we sought to identify a combination of an MEK1/2 inhibitor and IGF1R inhibitor, which would be tolerated in murine models and effective in both cell line and patient-derived xenograft models of RAS-mutant FN RMS.Experimental Design:Using proliferation and apoptosis assays, we studied the factorial effects of trametinib and ganitumab (AMG 479), a mAb with specificity for human and murine IGF1R, in a panel of RAS-mutant FN RMS cell lines. The molecular mechanism of the observed synergy was determined using conventional and capillary immunoassays. The efficacy and tolerability of trametinib/ganitumab was assessed using a panel of RAS-mutated cell-line and patient-derived RMS xenograft models.Results:Treatment with trametinib and ganitumab resulted in synergistic cellular growth inhibition in all cell lines tested and inhibition of tumor growth in four of six models of RAS-mutant RMS. The combination had little effect on body weight and did not produce thrombocytopenia, neutropenia, or hyperinsulinemia in tumor-bearing SCID beige mice. Mechanistically, ganitumab treatment prevented the phosphorylation of AKT induced by MEK inhibition alone. Therapeutic response to the combination was observed in models without a mutation in the PI3K/PTEN axis.Conclusions:We demonstrate that combined trametinib and ganitumab is effective in a genomically diverse panel of RAS-mutated FN RMS preclinical models. Our data also show that the trametinib/ganitumab combination likely has a favorable tolerability profile. These data support testing this combination in a phase I/II clinical trial for pediatric patients with relapsed or refractory RAS-mutated FN RMS.

Published

2023

25. supplementary table legend1 from Predicting Molecular Subtype and Survival of Rhabdomyosarcoma Patients Using Deep Learning of H&E Images: A Report from the Children's Oncology Group

Author

Javed Khan, Jack Collins, Jack F. Shern, Douglas S. Hawkins, Igor B. Kuznetsov, George Zaki, Seth M. Steinberg, Peter K. Bode, Rajkumar Venkatramani, Stephen X. Skapek, Hsien-Chao Chou, Jun S. Wei, Corinne M. Linardic, David Hall, Tammy Lo, Donald A. Barkauskas, Hyoyoung Choo-Wosoba, Erin R. Rudzinski, Marc Ladanyi, Curtis Lisle, Ben Somerville, Yanling Liu, G. Thomas Brown, Hyun Jung, and David Milewski

Abstract

supplementary table legend

Published

2023

26. Supplementary_Methods1 from Predicting Molecular Subtype and Survival of Rhabdomyosarcoma Patients Using Deep Learning of H&E Images: A Report from the Children's Oncology Group

Author

Javed Khan, Jack Collins, Jack F. Shern, Douglas S. Hawkins, Igor B. Kuznetsov, George Zaki, Seth M. Steinberg, Peter K. Bode, Rajkumar Venkatramani, Stephen X. Skapek, Hsien-Chao Chou, Jun S. Wei, Corinne M. Linardic, David Hall, Tammy Lo, Donald A. Barkauskas, Hyoyoung Choo-Wosoba, Erin R. Rudzinski, Marc Ladanyi, Curtis Lisle, Ben Somerville, Yanling Liu, G. Thomas Brown, Hyun Jung, and David Milewski

Abstract

Supplemental Description of the Rhabdomyosarcoma Web-based Application

Published

2023

27. Supplementary Table S1-S3 from Predicting Molecular Subtype and Survival of Rhabdomyosarcoma Patients Using Deep Learning of H&E Images: A Report from the Children's Oncology Group

Author

Javed Khan, Jack Collins, Jack F. Shern, Douglas S. Hawkins, Igor B. Kuznetsov, George Zaki, Seth M. Steinberg, Peter K. Bode, Rajkumar Venkatramani, Stephen X. Skapek, Hsien-Chao Chou, Jun S. Wei, Corinne M. Linardic, David Hall, Tammy Lo, Donald A. Barkauskas, Hyoyoung Choo-Wosoba, Erin R. Rudzinski, Marc Ladanyi, Curtis Lisle, Ben Somerville, Yanling Liu, G. Thomas Brown, Hyun Jung, and David Milewski

Abstract

Supplemental Table S1. Whole slide image tissue segmentation statistics by an expert pathologist and probability prediction using a trained convolutional neural network. Supplemental Table S2. Clinical and molecular characteristics of FN-RMS samples used for training models for mutation prediction. Yellow boxes indicate genes included in defining the RAS pathway. Supplemental Table S3. Clinical information with COG risk stratification of FN-RMS samples used for training a prognostication predictive CNN.

Published

2023

28. Supplementary Data File S4 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Sample Sizes

Published

2023

29. Figure S5 from Predicting Molecular Subtype and Survival of Rhabdomyosarcoma Patients Using Deep Learning of H&E Images: A Report from the Children's Oncology Group

Author

Javed Khan, Jack Collins, Jack F. Shern, Douglas S. Hawkins, Igor B. Kuznetsov, George Zaki, Seth M. Steinberg, Peter K. Bode, Rajkumar Venkatramani, Stephen X. Skapek, Hsien-Chao Chou, Jun S. Wei, Corinne M. Linardic, David Hall, Tammy Lo, Donald A. Barkauskas, Hyoyoung Choo-Wosoba, Erin R. Rudzinski, Marc Ladanyi, Curtis Lisle, Ben Somerville, Yanling Liu, G. Thomas Brown, Hyun Jung, and David Milewski

Abstract

Supplemental Figure S5. Frequency of mutations in COG and A.I. designated risk groups.

Published

2023

30. Supplementary Data File S2 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Related to Figure 1B

Published

2023

31. Supplementary Figure S2 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

The combination of trametinib and ganitumab does not induce hyperinsulinemia or hematologic adverse events in SCID beige mice

Published

2023

32. Supplementary Figure S4 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Effect of trametinib and ganitumab in additional cell culture models of RAS-mutated RMS

Published

2023

33. Figure S3 from Predicting Molecular Subtype and Survival of Rhabdomyosarcoma Patients Using Deep Learning of H&E Images: A Report from the Children's Oncology Group

Author

Javed Khan, Jack Collins, Jack F. Shern, Douglas S. Hawkins, Igor B. Kuznetsov, George Zaki, Seth M. Steinberg, Peter K. Bode, Rajkumar Venkatramani, Stephen X. Skapek, Hsien-Chao Chou, Jun S. Wei, Corinne M. Linardic, David Hall, Tammy Lo, Donald A. Barkauskas, Hyoyoung Choo-Wosoba, Erin R. Rudzinski, Marc Ladanyi, Curtis Lisle, Ben Somerville, Yanling Liu, G. Thomas Brown, Hyun Jung, and David Milewski

Abstract

Supplemental Figure S3. Sample partitioning for training and testing a RAS pathway mutation predictive model using K-fold cross-validation. Three independent experiments were trained on a random selection of samples for training, validation and testing.

Published

2023

34. Supplementary Data File S1 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Copy Number

Published

2023

35. Supplementary Data File S6 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Related to Figure 2 - SMS-CTR

Published

2023

36. Supplementary Data File S8 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Related to Figure 3

Published

2023

37. Supplementary Figure S5 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Mechanism of decreased PTEN expression in RD

Published

2023

38. Supplemental Data File S3 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Related to Figure 1D

Published

2023

39. Supplementary Figure S6 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Schematic depicting the impact of PTEN loss on sensitivity to MEK inhibition

Published

2023

40. Supplementary Figure S1 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Combining ganitumab with trametinib inhibits tumor growth and increases fibrosis in SMS-CTR but not RD xenografts

Published

2023

41. Figure S6 from Predicting Molecular Subtype and Survival of Rhabdomyosarcoma Patients Using Deep Learning of H&E Images: A Report from the Children's Oncology Group

Author

Javed Khan, Jack Collins, Jack F. Shern, Douglas S. Hawkins, Igor B. Kuznetsov, George Zaki, Seth M. Steinberg, Peter K. Bode, Rajkumar Venkatramani, Stephen X. Skapek, Hsien-Chao Chou, Jun S. Wei, Corinne M. Linardic, David Hall, Tammy Lo, Donald A. Barkauskas, Hyoyoung Choo-Wosoba, Erin R. Rudzinski, Marc Ladanyi, Curtis Lisle, Ben Somerville, Yanling Liu, G. Thomas Brown, Hyun Jung, and David Milewski

Abstract

Supplemental Figure S6. Graphical User Interface for tissue segmentation, MYOD1 mutation prediction, and risk prediction models.

Published

2023

42. Figure S4 from Predicting Molecular Subtype and Survival of Rhabdomyosarcoma Patients Using Deep Learning of H&E Images: A Report from the Children's Oncology Group

Author

Javed Khan, Jack Collins, Jack F. Shern, Douglas S. Hawkins, Igor B. Kuznetsov, George Zaki, Seth M. Steinberg, Peter K. Bode, Rajkumar Venkatramani, Stephen X. Skapek, Hsien-Chao Chou, Jun S. Wei, Corinne M. Linardic, David Hall, Tammy Lo, Donald A. Barkauskas, Hyoyoung Choo-Wosoba, Erin R. Rudzinski, Marc Ladanyi, Curtis Lisle, Ben Somerville, Yanling Liu, G. Thomas Brown, Hyun Jung, and David Milewski

Abstract

Supplemental Figure S4. Sample partitioning for training a MYOD1 mutation predictive model using K-fold cross-validation.

Published

2023

43. Supplementary Data File S7 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Related to Figure 2 - RD

Published

2023

44. Figure S1 from Predicting Molecular Subtype and Survival of Rhabdomyosarcoma Patients Using Deep Learning of H&E Images: A Report from the Children's Oncology Group

Author

Javed Khan, Jack Collins, Jack F. Shern, Douglas S. Hawkins, Igor B. Kuznetsov, George Zaki, Seth M. Steinberg, Peter K. Bode, Rajkumar Venkatramani, Stephen X. Skapek, Hsien-Chao Chou, Jun S. Wei, Corinne M. Linardic, David Hall, Tammy Lo, Donald A. Barkauskas, Hyoyoung Choo-Wosoba, Erin R. Rudzinski, Marc Ladanyi, Curtis Lisle, Ben Somerville, Yanling Liu, G. Thomas Brown, Hyun Jung, and David Milewski

Abstract

Supplemental Figure S1. Performance of A.I. model in classifying multiple samples from the same patient.

Published

2023

45. Supplementary Data File S5 from The Combination of Trametinib and Ganitumab is Effective in RAS-Mutated PAX-Fusion Negative Rhabdomyosarcoma Models

Author

Marielle E. Yohe, Javed Khan, Angelina V. Vaseva, Robert W. Robey, Robert L. Kortum, Frederic G. Barr, Simone Difilippantonio, Matthew D. Hall, Lu Chen, W. Douglas Figg, Jack F. Shern, Cody J. Peer, Noemi Kedei, Jin-Qiu Chen, Elijah F. Edmondson, Roberta Smith, Donna Butcher, Haiyan Lei, Xiaoling Luo, Priya Shankarappa, Parirokh Awasthi, Amy James, Christina M. Robinson, Kristine A. Isanogle, Wenyue Sun, Olivia L. Perkins, Stacey Stauffer, Angela Kim, William J.E. Frye, Nancy E. Sealover, David J. Liewehr, Jacob S. Roth, Xiaolin Wan, and Katie E. Hebron

Abstract

Baseline Statistics

Published

2023

46. Supplementary Figure Legends from Outcomes of Children and Adolescents with Advanced Hereditary Medullary Thyroid Carcinoma Treated with Vandetanib

Author

Brigitte C. Widemann, Jack F. Shern, John W. Glod, Paul S. Meltzer, Maria J. Merino, Frank M. Balis, Elizabeth Fox, Oxana Kapustina, Steven G. Waguespack, Maya Lodish, Seth M. Steinberg, Eva Dombi, Claudia Derse-Anthony, Haiyan Lei, Yuelin Zhu, Srivandana Akshintala, and Ira L. Kraft

Abstract

Legends for all included Supplementary Figures

Published

2023

47. Supplementary Figure 5 from Outcomes of Children and Adolescents with Advanced Hereditary Medullary Thyroid Carcinoma Treated with Vandetanib

Author

Brigitte C. Widemann, Jack F. Shern, John W. Glod, Paul S. Meltzer, Maria J. Merino, Frank M. Balis, Elizabeth Fox, Oxana Kapustina, Steven G. Waguespack, Maya Lodish, Seth M. Steinberg, Eva Dombi, Claudia Derse-Anthony, Haiyan Lei, Yuelin Zhu, Srivandana Akshintala, and Ira L. Kraft

Abstract

Heat map of cell cycle gene expression. Gene expression was normalized and compared between the primary MTC, metastasis one, and metastasis two lesions from the whole transcriptome RNA-seq data. Purple indicates lower and yellow indicates higher expression. Values to generate colors are z-scores across each genes' relative transcript levels [log2(FPKM)].

Published

2023

48. Supplementary Figure 3 from MultiDimensional ClinOmics for Precision Therapy of Children and Adolescent Young Adults with Relapsed and Refractory Cancer: A Report from the Center for Cancer Research

Author

Javed Khan, Jimmy C. Lin, Rosandra N. Kaplan, Melinda S. Merchant, Brigitte C. Widemann, Toby N. Trahair, James C. League-Pascual, Kip R. Hartman, Markku Miettinen, Thomas C. Badgett, Xinyu Wen, Nityashree Shivaprasad, Kathleen A. Calzone, Shile Zhang, Berkley Gryder, Marielle E. Yohe, Young K. Song, Jun S. Wei, Jack F. Shern, Sivasish Sindiri, Rajesh Patidar, Andrew S. Brohl, and Wendy Chang

Abstract

Using transcriptome data for expression profiling of tumors. Heatmap of transcriptome data allowing for expression profiling and clustering of diagnoses based on the 2000 most highly differentially expressed genes in comparison to the other cohort samples to validate tumor diagnosis. The diagnostic abbreviations are the same as in Figure 1 with the addition of EWLS for Ewing-like sarcoma.

Published

2023

49. Supplementary Method from MultiDimensional ClinOmics for Precision Therapy of Children and Adolescent Young Adults with Relapsed and Refractory Cancer: A Report from the Center for Cancer Research

Author

Javed Khan, Jimmy C. Lin, Rosandra N. Kaplan, Melinda S. Merchant, Brigitte C. Widemann, Toby N. Trahair, James C. League-Pascual, Kip R. Hartman, Markku Miettinen, Thomas C. Badgett, Xinyu Wen, Nityashree Shivaprasad, Kathleen A. Calzone, Shile Zhang, Berkley Gryder, Marielle E. Yohe, Young K. Song, Jun S. Wei, Jack F. Shern, Sivasish Sindiri, Rajesh Patidar, Andrew S. Brohl, and Wendy Chang

Abstract

Supplementary Method

Published

2023

50. Supplementary Figure 4 from MultiDimensional ClinOmics for Precision Therapy of Children and Adolescent Young Adults with Relapsed and Refractory Cancer: A Report from the Center for Cancer Research

Author

Javed Khan, Jimmy C. Lin, Rosandra N. Kaplan, Melinda S. Merchant, Brigitte C. Widemann, Toby N. Trahair, James C. League-Pascual, Kip R. Hartman, Markku Miettinen, Thomas C. Badgett, Xinyu Wen, Nityashree Shivaprasad, Kathleen A. Calzone, Shile Zhang, Berkley Gryder, Marielle E. Yohe, Young K. Song, Jun S. Wei, Jack F. Shern, Sivasish Sindiri, Rajesh Patidar, Andrew S. Brohl, and Wendy Chang

Abstract

Imaging from two clinical vignettes highlighting the importance of sequencing at diagnosis and relapse. A. An epithelioid inflammatory myofibroblastic sarcoma (Patient NCI0244) positive for a RANBP2-ALK fusion leading to activation of ALK was treated with targeted monotherapy. PET scans are shown in the top row. At initial diagnosis, abdominal tumors were located in the left upper quadrant with extensive FDG-avid peritoneal lesions. Clinical response after 8 months of targeted therapy with crizotinib was noted. First relapse with development of a recurrent nodule noted in between the right kidney and duodenum with pulmonary and hepatic metastases was observed after 14 months of crizotinib therapy. A secondary clinical response after treatment with ceritinib was obtained after 1 month of therapy, but was not maintained. The primary tumor sample derived cell line, labeled Tumor.1, did not contain an ALK I1171T mutation. Sanger validation confirmed the presence of an ALK p.I1171T mutation after targeted therapy with crizotinib and ceritinib. The patient's tumor samples all contained a RANBP2-ALK fusion, which was not present in the germline. B. A GNAQ Q209L mutation-positive melanoma (Patient NCI0155), treated with trametinib. The melanoma originated from the left frontotemporal scalp and left orbit, and was metastatic to regional lymph nodes, dura mater, liver, bone and lung as shown on CT (first column, first row) with PET avidity in metastases (first column, second row). WES and WTS of her tumor revealed a GNAQ Q209L mutation. The patient was treated with trametinib and had an initial mixed response, with loss of PET avidity of several liver metastases (second column, second row). However, progressive disease of the primary tumor was noted 5 months after initiating therapy, and PET/CT scans showed increased size of the primary tumor in the scalp (third column, first row)

Published

2023