Your search keyword '"Jeremy Gresham"' showing total 9 results

1. Adaptation and selection shape clonal evolution of tumors during residual disease and recurrence

Author

Andrea Walens, Jiaxing Lin, Jeffrey S. Damrauer, Brock McKinney, Ryan Lupo, Rachel Newcomb, Douglas B. Fox, Nathaniel W. Mabe, Jeremy Gresham, Zhecheng Sheng, Alexander B. Sibley, Tristan De Buysscher, Hemant Kelkar, Piotr A. Mieczkowski, Kouros Owzar, and James V. Alvarez

Subjects

Science

Abstract

The cellular composition of recurrent tumors can provide insight into resistance to therapy and inform on second line therapies. Here, using a genetically modified mouse, the authors perform barcoding experiments of the primary tumors to allow them to study the clonal dynamics of tumor recurrence.

Published

2020

2. bcSeq: an R package for fast sequence mapping in high-throughput shRNA and CRISPR screens.

Author

Jiaxing Lin, Jeremy Gresham, Tongrong Wang, So Young Kim, James Alvarez, Jeffrey S. Damrauer, Scott Floyd, Joshua A. Granek, Andrew S. Allen, Cliburn Chan, Jichun Xie, and Kouros Owzar

Published

2018

3. Whole-Exome Sequencing of Radiation-Induced Thymic Lymphoma in Mouse Models Identifies Notch1 Activation as a Driver of p53 Wild-Type Lymphoma

Author

Dadong Zhang, Jeremy Gresham, David G. Kirsch, Andrea R. Daniel, Isibel Caraballo, Lixia Luo, Chang-Lung Lee, Alexander B. Sibley, Stephanie Hasapis, Xiaodi Qin, Kennedy Davis Brock, Kouros Owzar, and Matthew J. Hilton

Subjects

Male, Cancer Research, Lymphoma, Somatic cell, Biology, medicine.disease_cause, Article, Mice, hemic and lymphatic diseases, Exome Sequencing, medicine, Animals, Receptor, Notch1, Exome sequencing, Thymic Lymphoma, Wild type, Thymus Neoplasms, medicine.disease, Transplantation, Disease Models, Animal, Thymocyte, Oncology, Cancer research, Female, Tumor Suppressor Protein p53, Carcinogenesis

Abstract

Mouse models of radiation-induced thymic lymphoma are widely used to study the development of radiation-induced blood cancers and to gain insights into the biology of human T-cell lymphoblastic leukemia/lymphoma. Here we aimed to identify key oncogenic drivers for the development of radiation-induced thymic lymphoma by performing whole-exome sequencing using tumors and paired normal tissues from mice with and without irradiation. Thymic lymphomas from irradiated wild-type (WT), p53+/−, and KrasLA1 mice were not observed to harbor significantly higher numbers of nonsynonymous somatic mutations compared with thymic lymphomas from unirradiated p53−/− mice. However, distinct patterns of recurrent mutations arose in genes that control the Notch1 signaling pathway based on the mutational status of p53. Preferential activation of Notch1 signaling in p53 WT lymphomas was also observed at the RNA and protein level. Reporter mice for activation of Notch1 signaling revealed that total-body irradiation (TBI) enriched Notch1hi CD44+ thymocytes that could propagate in vivo after thymocyte transplantation. Mechanistically, genetic inhibition of Notch1 signaling in immature thymocytes prevented formation of radiation-induced thymic lymphoma in p53 WT mice. Taken together, these results demonstrate a critical role of activated Notch1 signaling in driving multistep carcinogenesis of thymic lymphoma following TBI in p53 WT mice. Significance: These findings reveal the mutational landscape and key drivers in murine radiation-induced thymic lymphoma, a classic animal model that has been used to study radiation carcinogenesis for over 70 years.

Published

2021

4. The Human Tumor Atlas Network: Charting Tumor Transitions across Space and Time at Single-Cell Resolution

Author

Orit Rozenblatt-Rosen, Aviv Regev, Philipp Oberdoerffer, Tal Nawy, Anna Hupalowska, Jennifer E. Rood, Orr Ashenberg, Ethan Cerami, Robert J. Coffey, Emek Demir, Li Ding, Edward D. Esplin, James M. Ford, Jeremy Goecks, Sharmistha Ghosh, Joe W. Gray, Justin Guinney, Sean E. Hanlon, Shannon K. Hughes, E. Shelley Hwang, Christine A. Iacobuzio-Donahue, Judit Jané-Valbuena, Bruce E. Johnson, Ken S. Lau, Tracy Lively, Sarah A. Mazzilli, Dana Pe’er, Sandro Santagata, Alex K. Shalek, Denis Schapiro, Michael P. Snyder, Peter K. Sorger, Avrum E. Spira, Sudhir Srivastava, Kai Tan, Robert B. West, Elizabeth H. Williams, Denise Aberle, Samuel I. Achilefu, Foluso O. Ademuyiwa, Andrew C. Adey, Rebecca L. Aft, Rachana Agarwal, Ruben A. Aguilar, Fatemeh Alikarami, Viola Allaj, Christopher Amos, Robert A. Anders, Michael R. Angelo, Kristen Anton, Jon C. Aster, Ozgun Babur, Amir Bahmani, Akshay Balsubramani, David Barrett, Jennifer Beane, Diane E. Bender, Kathrin Bernt, Lynne Berry, Courtney B. Betts, Julie Bletz, Katie Blise, Adrienne Boire, Genevieve Boland, Alexander Borowsky, Kristopher Bosse, Matthew Bott, Ed Boyden, James Brooks, Raphael Bueno, Erik A. Burlingame, Qiuyin Cai, Joshua Campbell, Wagma Caravan, Hassan Chaib, Joseph M. Chan, Young Hwan Chang, Deyali Chatterjee, Ojasvi Chaudhary, Alyce A. Chen, Bob Chen, Changya Chen, Chia-hui Chen, Feng Chen, Yu-An Chen, Milan G. Chheda, Koei Chin, Roxanne Chiu, Shih-Kai Chu, Rodrigo Chuaqui, Jaeyoung Chun, Luis Cisneros, Graham A. Colditz, Kristina Cole, Natalie Collins, Kevin Contrepois, Lisa M. Coussens, Allison L. Creason, Daniel Crichton, Christina Curtis, Tanja Davidsen, Sherri R. Davies, Ino de Bruijn, Laura Dellostritto, Angelo De Marzo, David G. DeNardo, Dinh Diep, Sharon Diskin, Xengie Doan, Julia Drewes, Stephen Dubinett, Michael Dyer, Jacklynn Egger, Jennifer Eng, Barbara Engelhardt, Graham Erwin, Laura Esserman, Alex Felmeister, Heidi S. Feiler, Ryan C. Fields, Stephen Fisher, Keith Flaherty, Jennifer Flournoy, Angelo Fortunato, Allison Frangieh, Jennifer L. Frye, Robert S. Fulton, Danielle Galipeau, Siting Gan, Jianjiong Gao, Long Gao, Peng Gao, Vianne R. Gao, Tim Geiger, Ajit George, Gad Getz, Marios Giannakis, David L. Gibbs, William E. Gillanders, Simon P. Goedegebuure, Alanna Gould, Kate Gowers, William Greenleaf, Jeremy Gresham, Jennifer L. Guerriero, Tuhin K. Guha, Alexander R. Guimaraes, David Gutman, Nir Hacohen, Sean Hanlon, Casey R. Hansen, Olivier Harismendy, Kathleen A. Harris, Aaron Hata, Akimasa Hayashi, Cody Heiser, Karla Helvie, John M. Herndon, Gilliam Hirst, Frank Hodi, Travis Hollmann, Aaron Horning, James J. Hsieh, Shannon Hughes, Won Jae Huh, Stephen Hunger, Shelley E. Hwang, Heba Ijaz, Benjamin Izar, Connor A. Jacobson, Samuel Janes, Reyka G. Jayasinghe, Lihua Jiang, Brett E. Johnson, Bruce Johnson, Tao Ju, Humam Kadara, Klaus Kaestner, Jacob Kagan, Lukas Kalinke, Robert Keith, Aziz Khan, Warren Kibbe, Albert H. Kim, Erika Kim, Junhyong Kim, Annette Kolodzie, Mateusz Kopytra, Eran Kotler, Robert Krueger, Kostyantyn Krysan, Anshul Kundaje, Uri Ladabaum, Blue B. Lake, Huy Lam, Rozelle Laquindanum, Ashley M. Laughney, Hayan Lee, Marc Lenburg, Carina Leonard, Ignaty Leshchiner, Rochelle Levy, Jerry Li, Christine G. Lian, Kian-Huat Lim, Jia-Ren Lin, Yiyun Lin, Qi Liu, Ruiyang Liu, William J.R. Longabaugh, Teri Longacre, Cynthia X. Ma, Mary Catherine Macedonia, Tyler Madison, Christopher A. Maher, Anirban Maitra, Netta Makinen, Danika Makowski, Carlo Maley, Zoltan Maliga, Diego Mallo, John Maris, Nick Markham, Jeffrey Marks, Daniel Martinez, Robert J. Mashl, Ignas Masilionais, Jennifer Mason, Joan Massagué, Pierre Massion, Marissa Mattar, Richard Mazurchuk, Linas Mazutis, Eliot T. McKinley, Joshua F. McMichael, Daniel Merrick, Matthew Meyerson, Julia R. Miessner, Gordon B. Mills, Meredith Mills, Suman B. Mondal, Motomi Mori, Yuriko Mori, Elizabeth Moses, Yael Mosse, Jeremy L. Muhlich, George F. Murphy, Nicholas E. Navin, Michel Nederlof, Reid Ness, Stephanie Nevins, Milen Nikolov, Ajit Johnson Nirmal, Garry Nolan, Edward Novikov, Brendan O’Connell, Michael Offin, Stephen T. Oh, Anastasiya Olson, Alex Ooms, Miguel Ossandon, Kouros Owzar, Swapnil Parmar, Tasleema Patel, Gary J. Patti, Itsik Pe'er, Tao Peng, Daniel Persson, Marvin Petty, Hanspeter Pfister, Kornelia Polyak, Kamyar Pourfarhangi, Sidharth V. Puram, Qi Qiu, Álvaro Quintanal-Villalonga, Arjun Raj, Marisol Ramirez-Solano, Rumana Rashid, Ashley N. Reeb, Mary Reid, Adam Resnick, Sheila M. Reynolds, Jessica L. Riesterer, Scott Rodig, Joseph T. Roland, Sonia Rosenfield, Asaf Rotem, Sudipta Roy, Charles M. Rudin, Marc D. Ryser, Maria Santi-Vicini, Kazuhito Sato, Deborah Schrag, Nikolaus Schultz, Cynthia L. Sears, Rosalie C. Sears, Subrata Sen, Triparna Sen, Alex Shalek, Jeff Sheng, Quanhu Sheng, Kooresh I. Shoghi, Martha J. Shrubsole, Yu Shyr, Alexander B. Sibley, Kiara Siex, Alan J. Simmons, Dinah S. Singer, Shamilene Sivagnanam, Michal Slyper, Artem Sokolov, Sheng-Kwei Song, Austin Southard-Smith, Avrum Spira, Janet Stein, Phillip Storm, Elizabeth Stover, Siri H. Strand, Timothy Su, Damir Sudar, Ryan Sullivan, Lea Surrey, Mario Suvà, Nadezhda V. Terekhanova, Luke Ternes, Lisa Thammavong, Guillaume Thibault, George V. Thomas, Vésteinn Thorsson, Ellen Todres, Linh Tran, Madison Tyler, Yasin Uzun, Anil Vachani, Eliezer Van Allen, Simon Vandekar, Deborah J. Veis, Sébastien Vigneau, Arastoo Vossough, Angela Waanders, Nikhil Wagle, Liang-Bo Wang, Michael C. Wendl, Robert West, Chi-yun Wu, Hao Wu, Hung-Yi Wu, Matthew A. Wyczalkowski, Yubin Xie, Xiaolu Yang, Clarence Yapp, Wenbao Yu, Yinyin Yuan, Dadong Zhang, Kun Zhang, Mianlei Zhang, Nancy Zhang, Yantian Zhang, Yanyan Zhao, Daniel Cui Zhou, Zilu Zhou, Houxiang Zhu, Qin Zhu, Xiangzhu Zhu, Yuankun Zhu, and Xiaowei Zhuang

Subjects

Cell, Genomics, Computational biology, Tumor initiation, Biology, Article, General Biochemistry, Genetics and Molecular Biology, Metastasis, 03 medical and health sciences, Atlases as Topic, 0302 clinical medicine, Neoplasms, Tumor Microenvironment, medicine, Humans, Precision Medicine, 030304 developmental biology, 0303 health sciences, Atlas (topology), Cancer, medicine.disease, 3. Good health, Human tumor, Cell Transformation, Neoplastic, medicine.anatomical_structure, Single-Cell Analysis, Single point, 030217 neurology & neurosurgery

Abstract

Crucial transitions in cancer-including tumor initiation, local expansion, metastasis, and therapeutic resistance-involve complex interactions between cells within the dynamic tumor ecosystem. Transformative single-cell genomics technologies and spatial multiplex in situ methods now provide an opportunity to interrogate this complexity at unprecedented resolution. The Human Tumor Atlas Network (HTAN), part of the National Cancer Institute (NCI) Cancer Moonshot Initiative, will establish a clinical, experimental, computational, and organizational framework to generate informative and accessible three-dimensional atlases of cancer transitions for a diverse set of tumor types. This effort complements both ongoing efforts to map healthy organs and previous large-scale cancer genomics approaches focused on bulk sequencing at a single point in time. Generating single-cell, multiparametric, longitudinal atlases and integrating them with clinical outcomes should help identify novel predictive biomarkers and features as well as therapeutically relevant cell types, cell states, and cellular interactions across transitions. The resulting tumor atlases should have a profound impact on our understanding of cancer biology and have the potential to improve cancer detection, prevention, and therapeutic discovery for better precision-medicine treatments of cancer patients and those at risk for cancer.

Published

2020

5. Activation of Notch1 drives the development of radiation-induced thymic lymphoma in p53 wild-type mice

Author

Jeremy Gresham, David G. Kirsch, Lixia Luo, Dadong Zhang, Kennedy Davis Brock, Stephanie Hasapis, Alexander B. Sibley, Kouros Owzar, Matthew J. Hilton, Xiaodi Qin, Chang-Lung Lee, Isibel Caraballo, and Andrea R. Daniel

Subjects

biology, Somatic cell, CD44, medicine.disease_cause, medicine.disease, Lymphoma, Leukemia, In vivo, hemic and lymphatic diseases, medicine, biology.protein, Cancer research, Carcinogenesis, Gene, Thymic Lymphoma

Abstract

Mouse models of radiation-induced thymic lymphoma are widely used to study the development of radiation-induced blood cancers and to gain insights into the biology of human T-lymphoblastic leukemia/lymphoma. Here, we aimed to determine key oncogenic drivers for the development of radiation-induced thymic lymphoma by performing whole-exome sequencing using tumors and paired normal tissues from mice with and without irradiation. Thymic lymphomas from irradiated wild-type (WT), p53+/- and KrasLA1 mice were not observed to harbor significantly higher numbers of non-synonymous somatic mutations compared to thymic lymphomas from unirradiated p53-/- mice. However, we observed distinct patterns of recurrent mutations in genes that control the Notch1 signaling pathway based on the mutational status of p53. Preferential activation of Notch1 signaling in p53 WT lymphomas was also observed at the RNA and protein level. Using reporter mice for activation of the Notch1 signaling we observed that TBI enriched Notch1hi CD44+ thymocytes, which are capable of self-renewal in vivo. Mechanistically, genetic inhibition of Notch1 signaling in thymocytes prevented the formation of radiation-induced thymic lymphoma in p53 WT mice. Taken together, our results demonstrate a critical role of activated Notch1 signaling in driving multi-step carcinogenesis of thymic lymphoma following total-body irradiation in p53 WT mice.

Published

2020

6. Adaptation and Selection Shape Clonal Evolution During Residual Disease and Recurrence

Author

Kouros Owzar, Jeffrey S. Damrauer, Ryan Lupo, Jiaxing Lin, Nathaniel W. Mabe, Hemant Kelkar, Andrea Walens, James V. Alvarez, Rachel Newcomb, Douglas B. Fox, Piotr A. Mieczkowski, Jeremy Gresham, and T. De Buysscher

Subjects

0303 health sciences, Oncogene, Met amplification, Disease, Biology, medicine.disease, Somatic evolution in cancer, Minimal residual disease, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, 030220 oncology & carcinogenesis, Cancer research, medicine, Autocrine signalling, 030304 developmental biology, Dominance (genetics)

Abstract

SummaryThe survival of residual tumor cells following therapy and their eventual recurrence constitutes one of the biggest obstacles to obtaining cures in breast cancer, but it remains unclear how the clonal composition of tumors changes during tumor relapse. We used cellular barcoding to directly monitor clonal dynamics during tumor recurrence in a genetically engineered mouse model. We found that the clonal diversity of tumors progressively decreased during tumor regression, residual disease, and recurrence. Only a fraction of subclones survived oncogene withdrawal and persisted in residual tumors. The minimal residual disease phase itself was accompanied by a continued attrition of clones, suggesting an ongoing process of selection during dormancy. The reactivation of dormant residual cells into recurrent tumors followed several distinct evolutionary routes. Approximately half of the recurrent tumors exhibited a striking clonal dominance in which one or two subclones comprised the vast majority of the tumor. The majority of these clonal recurrent tumors exhibited evidence of de novo acquisition of Met amplification, and were sensitive to small-molecule Met inhibitors. A second group of recurrent tumors exhibited marked polyclonality, with thousands of subclones and a clonal architecture very similar to primary tumors. These polyclonal recurrent tumors were not sensitive to Met inhibitors, but were instead dependent upon an autocrine IL-6 – Stat3 pathway. These results suggest that the survival and reactivation of dormant tumors can proceed via multiple independent routes, producing recurrent tumors with distinct clonal composition, genetic alterations, and drug sensitivities.

Published

2020

7. Adaptation and selection shape clonal evolution of tumors during residual disease and recurrence

Author

Zhecheng Sheng, Hemant Kelkar, Brock McKinney, Kouros Owzar, Tristan De Buysscher, Nathaniel W. Mabe, Rachel Newcomb, Ryan Lupo, Piotr A. Mieczkowski, Andrea Walens, Jeffrey S. Damrauer, Alexander B. Sibley, Jeremy Gresham, Douglas B. Fox, Jiaxing Lin, and James V. Alvarez

Subjects

0301 basic medicine, Epithelial-Mesenchymal Transition, Lung Neoplasms, Receptor, ErbB-2, Science, Tumour heterogeneity, General Physics and Astronomy, Mice, Nude, Tumor cells, Breast Neoplasms, Disease, Biology, Somatic evolution in cancer, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Breast cancer, Crizotinib, Cell Line, Tumor, medicine, Animals, Humans, lcsh:Science, Clonal diversity, Dominance (genetics), Multidisciplinary, Clonal architecture, High-Throughput Nucleotide Sequencing, General Chemistry, Proto-Oncogene Proteins c-met, medicine.disease, Xenograft Model Antitumor Assays, Tumor recurrence, Gene Expression Regulation, Neoplastic, 030104 developmental biology, 030220 oncology & carcinogenesis, Doxycycline, Cancer research, lcsh:Q, Female, Neoplasm Recurrence, Local, Single-Cell Analysis

Abstract

The survival and recurrence of residual tumor cells following therapy constitutes one of the biggest obstacles to obtaining cures in breast cancer, but it remains unclear how the clonal composition of tumors changes during relapse. We use cellular barcoding to monitor clonal dynamics during tumor recurrence in vivo. We find that clonal diversity decreases during tumor regression, residual disease, and recurrence. The recurrence of dormant residual cells follows several distinct routes. Approximately half of the recurrent tumors exhibit clonal dominance with a small number of subclones comprising the vast majority of the tumor; these clonal recurrences are frequently dependent upon Met gene amplification. A second group of recurrent tumors comprises thousands of subclones, has a clonal architecture similar to primary tumors, and is dependent upon the Jak/Stat pathway. Thus the regrowth of dormant tumors proceeds via multiple routes, producing recurrent tumors with distinct clonal composition, genetic alterations, and drug sensitivities., The cellular composition of recurrent tumors can provide insight into resistance to therapy and inform on second line therapies. Here, using a genetically modified mouse, the authors perform barcoding experiments of the primary tumors to allow them to study the clonal dynamics of tumor recurrence.

Published

2019

8. Mutational landscape in genetically engineered, carcinogen-induced, and radiation-induced mouse sarcoma

Author

David G. Kirsch, Andrea R. Daniel, Lixia Luo, David Van Mater, Amy J. Wisdom, Xi Wang, Yvonne M. Mowery, Alexander B. Sibley, Kouros Owzar, Jeremy Gresham, Isibel Caraballo, Dadong Zhang, Joe R. Delaney, Xiaodi Qin, and Chang-Lung Lee

Subjects

0301 basic medicine, Genome instability, medicine.medical_specialty, Neoplasms, Radiation-Induced, Carcinogenesis, DNA Mutational Analysis, Biology, medicine.disease_cause, Genomic Instability, Proto-Oncogene Proteins p21(ras), 03 medical and health sciences, Mice, 0302 clinical medicine, Molecular genetics, Exome Sequencing, medicine, Animals, Humans, Copy-number variation, Hippo signaling pathway, Sarcoma, General Medicine, Neoplasms, Experimental, Oncogenes, medicine.disease, 030104 developmental biology, 030220 oncology & carcinogenesis, Cancer research, Carcinogens, KRAS, Tumor Suppressor Protein p53, FAT1, Research Article, Methylcholanthrene

Abstract

Cancer development is influenced by hereditary mutations, somatic mutations due to random errors in DNA replication, or external factors. It remains unclear how distinct cell-intrinsic and -extrinsic factors affect oncogenesis within the same tissue type. We investigated murine soft-tissue sarcomas generated by oncogenic alterations (Kras(G12D) activation and p53 deletion), carcinogens (3-methylcholanthrene [MCA] or ionizing radiation), and both factors in a potentially novel model (MCA plus p53 deletion). Whole-exome sequencing demonstrated distinct mutational signatures in individual sarcoma cohorts. MCA-induced sarcomas exhibited high mutational burden and predominantly G-to-T transversions, while radiation-induced sarcomas exhibited low mutational burden and a distinct genetic signature characterized by C-to-T transitions. The insertion-deletion/substitution ratio and number of gene copy number variations were high for radiation-induced sarcomas. MCA-induced tumors generated on a p53-deficient background showed the highest genomic instability. MCA-induced sarcomas harbored mutations in putative cancer driver genes that regulate MAPK signaling (Kras and Nf1) and the Hippo pathway (Fat1 and Fat4). In contrast, radiation-induced sarcomas and Kras(G12D) p53(–/–) sarcomas did not harbor recurrent oncogenic mutations; rather, they exhibited amplifications of specific oncogenes: Kras and Myc in Kras(G12D) p53(–/–) sarcomas and Met and Yap1 for radiation-induced sarcomas. These results reveal that different initiating events drive oncogenesis through distinct mechanisms.

Published

2019

9. Targeted Exome Sequencing of the Cancer Genome in Patients with Very High-risk Bladder Cancer

Author

Wiguins Etienne, Stephen Szabo, Brant A. Inman, Yuan Wu, Alexander B. Sibley, Jeremy Gresham, Kouros Owzar, Jennifer A. Freedman, Joel Greshock, Christopher Moy, Thomas A. Longo, Yuchen Bai, Kathleen F. McGinley, and Hui Zhou

Subjects

Male, 0301 basic medicine, Mutation rate, DNA repair, Urology, medicine.medical_treatment, Antineoplastic Agents, Polymorphism, Single Nucleotide, Somatic evolution in cancer, Epigenesis, Genetic, Metastasis, Targeted therapy, 03 medical and health sciences, 0302 clinical medicine, Mutation Rate, Exome Sequencing, Humans, Medicine, Epigenetics, Neoplasm Metastasis, Exome sequencing, Aged, Neoplasm Staging, Bladder cancer, business.industry, Middle Aged, medicine.disease, Neoadjuvant Therapy, United States, Patient Outcome Assessment, 030104 developmental biology, Urinary Bladder Neoplasms, 030220 oncology & carcinogenesis, Cancer research, Female, business

Abstract

We completed targeted exome sequencing of the tumors of 50 patients with pTis–pT4b bladder cancer. Mutations were categorized by type, stratified against previously identified cancer loci in the Catalogue of Somatic Mutations in Cancer and The Cancer Genome Atlas databases, and evaluated in pathway analysis and comutation plots. We analyzed mutation associations with receipt of neoadjuvant chemotherapy, nodal involvement, metastatic disease development, and survival. Compared with The Cancer Genome Atlas, we found higher mutation rates in genes encoding products involved in epigenetic regulation and cell cycle regulation. Of the pathways examined, PI3K/mTOR and Cell Cycle/DNA Repair exhibited the greatest frequencies of mutation. RB1 and TP53 , as well as NF1 and PIK3CA were frequently comutated. We identified no association between mutations in specific genes and key clinical outcomes of interest when corrected for multiple testing. Discovery phase analysis of the somatic mutations in 50 high-risk bladder cancer patients revealed novel mutations and mutational patterns, which may be useful for developing targeted therapy regimens or new biomarkers for patients at very high risk of disease metastasis and death. Patient summary In this report we found known, as well as previously unreported, genetic mutations in the tumors of patients with high-risk bladder cancer. These mutations, if validated, may serve as actionable targets for new trials.

Published

2016