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1. AR coactivators, CBP/p300, are critical mediators of DNA repair in prostate cancer

Author

Sardar, Sumaira, McNair, Christopher M., Ravindranath, Lakshmi, Chand, Saswati N., Yuan, Wei, Bogdan, Denisa, Welti, Jon, Sharp, Adam, Ryan, Natalie K., Knudsen, Liam A., Schiewer, Matthew J., DeArment, Elise G., Janas, Thomas, Su, Xiaofeng A., Butler, Lisa M., de Bono, Johann S., Frese, Kris, Brooks, Nigel, Pegg, Neil, Knudsen, Karen E., and Shafi, Ayesha A.

Published
2024
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2. Where Do We Go from Here?

Author

Barta, Julie A., Knudsen, Karen E., Kane, Gregory C., editor, Barta, Julie A., editor, Myers, Ronald E., editor, and Evans III, Nathaniel R., editor

Published
2023
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4. Implementation of Germline Testing for Prostate Cancer: Philadelphia Prostate Cancer Consensus Conference 2019.

Author

Giri, Veda N, Knudsen, Karen E, Kelly, William K, Cheng, Heather H, Cooney, Kathleen A, Cookson, Michael S, Dahut, William, Weissman, Scott, Soule, Howard R, Petrylak, Daniel P, Dicker, Adam P, AlDubayan, Saud H, Toland, Amanda E, Pritchard, Colin C, Pettaway, Curtis A, Daly, Mary B, Mohler, James L, Parsons, J Kellogg, Carroll, Peter R, Pilarski, Robert, Blanco, Amie, Woodson, Ashley, Rahm, Alanna, Taplin, Mary-Ellen, Polascik, Thomas J, Helfand, Brian T, Hyatt, Colette, Morgans, Alicia K, Feng, Felix, Mullane, Michael, Powers, Jacqueline, Concepcion, Raoul, Lin, Daniel W, Wender, Richard, Mark, James Ryan, Costello, Anthony, Burnett, Arthur L, Sartor, Oliver, Isaacs, William B, Xu, Jianfeng, Weitzel, Jeffrey, Andriole, Gerald L, Beltran, Himisha, Briganti, Alberto, Byrne, Lindsey, Calvaresi, Anne, Chandrasekar, Thenappan, Chen, David YT, Den, Robert B, Dobi, Albert, Crawford, E David, Eastham, James, Eggener, Scott, Freedman, Matthew L, Garnick, Marc, Gomella, Patrick T, Handley, Nathan, Hurwitz, Mark D, Izes, Joseph, Karnes, R Jeffrey, Lallas, Costas, Languino, Lucia, Loeb, Stacy, Lopez, Ana Maria, Loughlin, Kevin R, Lu-Yao, Grace, Malkowicz, S Bruce, Mann, Mark, Mille, Patrick, Miner, Martin M, Morgan, Todd, Moreno, Jose, Mucci, Lorelei, Myers, Ronald E, Nielsen, Sarah M, O'Neil, Brock, Pinover, Wayne, Pinto, Peter, Poage, Wendy, Raj, Ganesh V, Rebbeck, Timothy R, Ryan, Charles, Sandler, Howard, Schiewer, Matthew, Scott, E Michael D, Szymaniak, Brittany, Tester, William, Trabulsi, Edouard J, Vapiwala, Neha, Yu, Evan Y, Zeigler-Johnson, Charnita, and Gomella, Leonard G

Subjects
Biotechnology, Aging, Genetics, Prevention, Clinical Research, Cancer, Prostate Cancer, Genetic Testing, Urologic Diseases, Health Services, Good Health and Well Being, Germ-Line Mutation, History, 20th Century, Humans, Male, Prostatic Neoplasms, Clinical Sciences, Oncology and Carcinogenesis, Oncology & Carcinogenesis
Abstract

PurposeGermline testing (GT) is a central feature of prostate cancer (PCA) treatment, management, and hereditary cancer assessment. Critical needs include optimized multigene testing strategies that incorporate evolving genetic data, consistency in GT indications and management, and alternate genetic evaluation models that address the rising demand for genetic services.MethodsA multidisciplinary consensus conference that included experts, stakeholders, and national organization leaders was convened in response to current practice challenges and to develop a genetic implementation framework. Evidence review informed questions using the modified Delphi model. The final framework included criteria with strong (> 75%) agreement (Recommend) or moderate (50% to 74%) agreement (Consider).ResultsLarge germline panels and somatic testing were recommended for metastatic PCA. Reflex testing-initial testing of priority genes followed by expanded testing-was suggested for multiple scenarios. Metastatic disease or family history suggestive of hereditary PCA was recommended for GT. Additional family history and pathologic criteria garnered moderate consensus. Priority genes to test for metastatic disease treatment included BRCA2, BRCA1, and mismatch repair genes, with broader testing, such as ATM, for clinical trial eligibility. BRCA2 was recommended for active surveillance discussions. Screening starting at age 40 years or 10 years before the youngest PCA diagnosis in a family was recommended for BRCA2 carriers, with consideration in HOXB13, BRCA1, ATM, and mismatch repair carriers. Collaborative (point-of-care) evaluation models between health care and genetic providers was endorsed to address the genetic counseling shortage. The genetic evaluation framework included optimal pretest informed consent, post-test discussion, cascade testing, and technology-based approaches.ConclusionThis multidisciplinary, consensus-driven PCA genetic implementation framework provides novel guidance to clinicians and patients tailored to the precision era. Multiple research, education, and policy needs remain of importance.

Published
2020

5. The DNA methylation landscape of advanced prostate cancer

Author

Zhao, Shuang G, Chen, William S, Li, Haolong, Foye, Adam, Zhang, Meng, Sjöström, Martin, Aggarwal, Rahul, Playdle, Denise, Liao, Arnold, Alumkal, Joshi J, Das, Rajdeep, Chou, Jonathan, Hua, Junjie T, Barnard, Travis J, Bailey, Adina M, Chow, Eric D, Perry, Marc D, Dang, Ha X, Yang, Rendong, Moussavi-Baygi, Ruhollah, Zhang, Li, Alshalalfa, Mohammed, Laura Chang, S, Houlahan, Kathleen E, Shiah, Yu-Jia, Beer, Tomasz M, Thomas, George, Chi, Kim N, Gleave, Martin, Zoubeidi, Amina, Reiter, Robert E, Rettig, Matthew B, Witte, Owen, Yvonne Kim, M, Fong, Lawrence, Spratt, Daniel E, Morgan, Todd M, Bose, Rohit, Huang, Franklin W, Li, Hui, Chesner, Lisa, Shenoy, Tanushree, Goodarzi, Hani, Asangani, Irfan A, Sandhu, Shahneen, Lang, Joshua M, Mahajan, Nupam P, Lara, Primo N, Evans, Christopher P, Febbo, Phillip, Batzoglou, Serafim, Knudsen, Karen E, He, Housheng H, Huang, Jiaoti, Zwart, Wilbert, Costello, Joseph F, Luo, Jianhua, Tomlins, Scott A, Wyatt, Alexander W, Dehm, Scott M, Ashworth, Alan, Gilbert, Luke A, Boutros, Paul C, Farh, Kyle, Chinnaiyan, Arul M, Maher, Christopher A, Small, Eric J, Quigley, David A, and Feng, Felix Y

Subjects
Biological Sciences, Bioinformatics and Computational Biology, Genetics, Cancer, Prostate Cancer, Human Genome, Urologic Diseases, Cancer Genomics, Biotechnology, 2.1 Biological and endogenous factors, Aged, Aged, 80 and over, Carcinogenesis, DNA Methylation, Epigenomics, Gene Expression Regulation, Neoplastic, Genome, Humans, Male, Middle Aged, Mutation, Prospective Studies, Prostatic Neoplasms, Sequence Analysis, DNA, Exome Sequencing, Whole Genome Sequencing, Medical and Health Sciences, Developmental Biology, Agricultural biotechnology, Bioinformatics and computational biology
Abstract

Although DNA methylation is a key regulator of gene expression, the comprehensive methylation landscape of metastatic cancer has never been defined. Through whole-genome bisulfite sequencing paired with deep whole-genome and transcriptome sequencing of 100 castration-resistant prostate metastases, we discovered alterations affecting driver genes that were detectable only with integrated whole-genome approaches. Notably, we observed that 22% of tumors exhibited a novel epigenomic subtype associated with hypermethylation and somatic mutations in TET2, DNMT3B, IDH1 and BRAF. We also identified intergenic regions where methylation is associated with RNA expression of the oncogenic driver genes AR, MYC and ERG. Finally, we showed that differential methylation during progression preferentially occurs at somatic mutational hotspots and putative regulatory regions. This study is a large integrated study of whole-genome, whole-methylome and whole-transcriptome sequencing in metastatic cancer that provides a comprehensive overview of the important regulatory role of methylation in metastatic castration-resistant prostate cancer.

Published
2020

6. DNA-Dependent Protein Kinase Drives Prostate Cancer Progression through Transcriptional Regulation of the Wnt Signaling Pathway

Author

Kothari, Vishal, Goodwin, Jonathan F, Zhao, Shuang G, Drake, Justin M, Yin, Yi, Chang, S Laura, Evans, Joseph R, Wilder-Romans, Kari, Gabbara, Kristina, Dylgjeri, Emanuela, Chou, Jonathan, Sun, Grace, Tomlins, Scott A, Mehra, Rohit, Hege, Kristen, Filvaroff, Ellen H, Schaeffer, Edward M, Karnes, R Jeffrey, Quigley, David A, Rathkopf, Dana E, He, Housheng H, Speers, Corey, Spratt, Daniel E, Gilbert, Luke A, Ashworth, Alan, Chinnaiyan, Arul M, Raj, Ganesh V, Knudsen, Karen E, and Feng, Felix Y

Subjects
Prostate Cancer, Urologic Diseases, Genetics, Aging, Cancer, 2.1 Biological and endogenous factors, Aetiology, Animals, Biomarkers, Tumor, Cell Line, Tumor, Cell Movement, DNA-Activated Protein Kinase, Disease Models, Animal, Disease Progression, Gene Expression Profiling, Gene Expression Regulation, Neoplastic, Gene Knockdown Techniques, Heterografts, Humans, Male, Mice, Neoplasm Metastasis, Phenotype, Prostatic Neoplasms, Protein Binding, RNA, Small Interfering, Transcription, Genetic, Wnt Signaling Pathway, Oncology and Carcinogenesis, Oncology & Carcinogenesis
Abstract

PURPOSE:Protein kinases are known to play a prominent role in oncogenic progression across multiple cancer subtypes, yet their role in prostate cancer progression remains underexplored. The purpose of this study was to identify kinases that drive prostate cancer progression.Experimental Design: To discover kinases that drive prostate cancer progression, we investigated the association between gene expression of all known kinases and long-term clinical outcomes in tumor samples from 545 patients with high-risk disease. We evaluated the impact of genetic and pharmacologic inhibition of the most significant kinase associated with metastatic progression in vitro and in vivo. RESULTS:DNA-dependent protein kinase (DNAPK) was identified as the most significant kinase associated with metastatic progression in high-risk prostate cancer. Inhibition of DNAPK suppressed the growth of both AR-dependent and AR-independent prostate cancer cells. Gene set enrichment analysis nominated Wnt as the top pathway associated with DNAPK. We found that DNAPK interacts with the Wnt transcription factor LEF1 and is critical for LEF1-mediated transcription. CONCLUSIONS:Our data show that DNAPK drives prostate cancer progression through transcriptional regulation of Wnt signaling and is an attractive therapeutic target in aggressive prostate cancer.

Published
2019

7. Novel RB1-Loss Transcriptomic Signature Is Associated with Poor Clinical Outcomes across Cancer Types

Author

Chen, William S, Alshalalfa, Mohammed, Zhao, Shuang G, Liu, Yang, Mahal, Brandon A, Quigley, David A, Wei, Ting, Davicioni, Elai, Rebbeck, Timothy R, Kantoff, Philip W, Maher, Christopher A, Knudsen, Karen E, Small, Eric J, Nguyen, Paul L, and Feng, Felix Y

Subjects
Rare Diseases, Genetics, Human Genome, Clinical Research, Cancer, Good Health and Well Being, Biomarkers, Tumor, Disease Progression, Humans, Male, Neoplasms, Prognosis, Transcriptome, Oncology and Carcinogenesis, Oncology & Carcinogenesis
Abstract

PurposeRb-pathway disruption is of great clinical interest, as it has been shown to predict outcomes in multiple cancers. We sought to develop a transcriptomic signature for detecting biallelic RB1 loss (RBS) that could be used to assess the clinical implications of RB1 loss on a pan-cancer scale.Experimental designWe utilized data from the Cancer Cell Line Encyclopedia (N = 995) to develop the first pan-cancer transcriptomic signature for predicting biallelic RB1 loss (RBS). Model accuracy was validated using The Cancer Genome Atlas (TCGA) Pan-Cancer dataset (N = 11,007). RBS was then used to assess the clinical relevance of biallelic RB1 loss in TCGA Pan-Cancer and in an additional metastatic castration-resistant prostate cancer (mCRPC) cohort.ResultsRBS outperformed the leading existing signature for detecting RB1 biallelic loss across all cancer types in TCGA Pan-Cancer (AUC, 0.89 vs. 0.66). High RBS (RB1 biallelic loss) was associated with promoter hypermethylation (P = 0.008) and gene body hypomethylation (P = 0.002), suggesting RBS could detect epigenetic gene silencing. TCGA Pan-Cancer clinical analyses revealed that high RBS was associated with short progression-free (P < 0.00001), overall (P = 0.0004), and disease-specific (P < 0.00001) survival. On multivariable analyses, high RBS was predictive of shorter progression-free survival in TCGA Pan-Cancer (P = 0.03) and of shorter overall survival in mCRPC (P = 0.004) independently of the number of DNA alterations in RB1.ConclusionsOur study provides the first validated tool to assess RB1 biallelic loss across cancer types based on gene expression. RBS can be useful for analyzing datasets with or without DNA-sequencing results to investigate the emerging prognostic and treatment implications of Rb-pathway disruption.See related commentary by Choudhury and Beltran, p. 4199.

Published
2019

9. Genomic Hallmarks and Structural Variation in Metastatic Prostate Cancer.

Author

Quigley, David A, Dang, Ha X, Zhao, Shuang G, Lloyd, Paul, Aggarwal, Rahul, Alumkal, Joshi J, Foye, Adam, Kothari, Vishal, Perry, Marc D, Bailey, Adina M, Playdle, Denise, Barnard, Travis J, Zhang, Li, Zhang, Jin, Youngren, Jack F, Cieslik, Marcin P, Parolia, Abhijit, Beer, Tomasz M, Thomas, George, Chi, Kim N, Gleave, Martin, Lack, Nathan A, Zoubeidi, Amina, Reiter, Robert E, Rettig, Matthew B, Witte, Owen, Ryan, Charles J, Fong, Lawrence, Kim, Won, Friedlander, Terence, Chou, Jonathan, Li, Haolong, Das, Rajdeep, Li, Hui, Moussavi-Baygi, Ruhollah, Goodarzi, Hani, Gilbert, Luke A, Lara, Primo N, Evans, Christopher P, Goldstein, Theodore C, Stuart, Joshua M, Tomlins, Scott A, Spratt, Daniel E, Cheetham, R Keira, Cheng, Donavan T, Farh, Kyle, Gehring, Julian S, Hakenberg, Jörg, Liao, Arnold, Febbo, Philip G, Shon, John, Sickler, Brad, Batzoglou, Serafim, Knudsen, Karen E, He, Housheng H, Huang, Jiaoti, Wyatt, Alexander W, Dehm, Scott M, Ashworth, Alan, Chinnaiyan, Arul M, Maher, Christopher A, Small, Eric J, and Feng, Felix Y

Subjects
Humans, Prostatic Neoplasms, Neoplasm Metastasis, Cyclin-Dependent Kinases, Proto-Oncogene Proteins c-myc, BRCA2 Protein, Receptors, Androgen, Gene Expression Profiling, Genomics, Tandem Repeat Sequences, Mutation, Aged, Aged, 80 and over, Middle Aged, Male, Tumor Suppressor Protein p53, Genomic Structural Variation, DNA Copy Number Variations, Exome, Whole Genome Sequencing, BRCA2, androgen receptor, castration resistant prostate cancer, chromothripsis, gene fusion, genomics, metastases, structural variation, tandem duplication, whole-genome sequencing, Biological Sciences, Medical and Health Sciences, Developmental Biology
Abstract

While mutations affecting protein-coding regions have been examined across many cancers, structural variants at the genome-wide level are still poorly defined. Through integrative deep whole-genome and -transcriptome analysis of 101 castration-resistant prostate cancer metastases (109X tumor/38X normal coverage), we identified structural variants altering critical regulators of tumorigenesis and progression not detectable by exome approaches. Notably, we observed amplification of an intergenic enhancer region 624 kb upstream of the androgen receptor (AR) in 81% of patients, correlating with increased AR expression. Tandem duplication hotspots also occur near MYC, in lncRNAs associated with post-translational MYC regulation. Classes of structural variations were linked to distinct DNA repair deficiencies, suggesting their etiology, including associations of CDK12 mutation with tandem duplications, TP53 inactivation with inverted rearrangements and chromothripsis, and BRCA2 inactivation with deletions. Together, these observations provide a comprehensive view of how structural variations affect critical regulators in metastatic prostate cancer.

Published
2018

10. Targeting Androgen Receptor and DNA Repair in Metastatic Castration-Resistant Prostate Cancer: Results From NCI 9012

Author

Hussain, Maha, Daignault-Newton, Stephanie, Twardowski, Przemyslaw W, Albany, Costantine, Stein, Mark N, Kunju, Lakshmi P, Siddiqui, Javed, Wu, Yi-Mi, Robinson, Dan, Lonigro, Robert J, Cao, Xuhong, Tomlins, Scott A, Mehra, Rohit, Cooney, Kathleen A, Montgomery, Bruce, Antonarakis, Emmanuel S, Shevrin, Daniel H, Corn, Paul G, Whang, Young E, Smith, David C, Caram, Megan V, Knudsen, Karen E, Stadler, Walter M, Feng, Felix Y, and Chinnaiyan, Arul M

Subjects
Genetics, Prostate Cancer, Cancer, Urologic Diseases, Aged, Aged, 80 and over, Androstenes, Antineoplastic Combined Chemotherapy Protocols, Benzimidazoles, Biomarkers, Tumor, DNA Repair, Humans, Male, Middle Aged, Molecular Targeted Therapy, Neoplasm Metastasis, Poly(ADP-ribose) Polymerase Inhibitors, Prednisone, Prostatic Neoplasms, Castration-Resistant, Proto-Oncogene Proteins c-ets, Receptors, Androgen, Clinical Sciences, Oncology and Carcinogenesis, Oncology & Carcinogenesis
Abstract

Purpose To determine whether cotargeting poly (ADP-ribose) polymerase-1 plus androgen receptor is superior to androgen receptor inhibition in metastatic castration-resistant prostate cancer (mCRPC) and whether ETS fusions predict response. Patients and Methods Patients underwent metastatic site biopsy and were stratified by ETS status and randomly assigned to abiraterone plus prednisone without (arm A) or with veliparib (arm B). Primary objectives were: confirmed prostate-specific antigen (PSA) response rate (RR) and whether ETS fusions predicted response. Secondary objectives were: safety, measurable disease RR (mRR), progression-free survival (PFS), and molecular biomarker analysis. A total of 148 patients were randomly assigned to detect a 20% PSA RR improvement. Results A total of 148 patients with mCRPC were randomly assigned: arm A, n = 72; arm B, n = 76. There were no differences in PSA RR (63.9% v 72.4%; P = .27), mRR (45.0% v 52.2%; P = .51), or median PFS (10.1 v 11 months; P = .99). ETS fusions did not predict response. Exploratory analysis of tumor sequencing (80 patients) revealed: 41 patients (51%) were ETS positive, 20 (25%) had DNA-damage repair defect (DRD), 41 (51%) had AR amplification or copy gain, 34 (43%) had PTEN mutation, 33 (41%) had TP53 mutation, 39 (49%) had PIK3CA pathway activation, and 12 (15%) had WNT pathway alteration. Patients with DRD had significantly higher PSA RR (90% v 56.7%; P = .007) and mRR (87.5% v 38.6%; P = .001), PSA decline ≥ 90% (75% v 25%; P = .001), and longer median PFS (14.5 v 8.1 months; P = .025) versus those with wild-type tumors. Median PFS was longer in patients with normal PTEN (13.5 v 6.7 months; P = .02), TP53 (13.5 v 7.7 months; P = .01), and PIK3CA (13.8 v 8.3 months; P = .03) versus those with mutation or activation. In multivariable analysis adjusting for clinical covariates, DRD association with PFS remained significant. Conclusion Veliparib and ETS status did not affect response. Exploratory analysis identified a novel DRD association with mCRPC outcomes.

Published
2018

11. Role of Genetic Testing for Inherited Prostate Cancer Risk: Philadelphia Prostate Cancer Consensus Conference 2017.

Author

Giri, Veda N, Knudsen, Karen E, Kelly, William K, Abida, Wassim, Andriole, Gerald L, Bangma, Chris H, Bekelman, Justin E, Benson, Mitchell C, Blanco, Amie, Burnett, Arthur, Catalona, William J, Cooney, Kathleen A, Cooperberg, Matthew, Crawford, David E, Den, Robert B, Dicker, Adam P, Eggener, Scott, Fleshner, Neil, Freedman, Matthew L, Hamdy, Freddie C, Hoffman-Censits, Jean, Hurwitz, Mark D, Hyatt, Colette, Isaacs, William B, Kane, Christopher J, Kantoff, Philip, Karnes, R Jeffrey, Karsh, Lawrence I, Klein, Eric A, Lin, Daniel W, Loughlin, Kevin R, Lu-Yao, Grace, Malkowicz, S Bruce, Mann, Mark J, Mark, James R, McCue, Peter A, Miner, Martin M, Morgan, Todd, Moul, Judd W, Myers, Ronald E, Nielsen, Sarah M, Obeid, Elias, Pavlovich, Christian P, Peiper, Stephen C, Penson, David F, Petrylak, Daniel, Pettaway, Curtis A, Pilarski, Robert, Pinto, Peter A, Poage, Wendy, Raj, Ganesh V, Rebbeck, Timothy R, Robson, Mark E, Rosenberg, Matt T, Sandler, Howard, Sartor, Oliver, Schaeffer, Edward, Schwartz, Gordon F, Shahin, Mark S, Shore, Neal D, Shuch, Brian, Soule, Howard R, Tomlins, Scott A, Trabulsi, Edouard J, Uzzo, Robert, Vander Griend, Donald J, Walsh, Patrick C, Weil, Carol J, Wender, Richard, and Gomella, Leonard G

Subjects
Humans, Prostatic Neoplasms, Genetic Predisposition to Disease, Prognosis, Risk Factors, Predictive Value of Tests, Pedigree, Age Factors, Heredity, Phenotype, Adult, Aged, Middle Aged, Male, Genetic Testing, Biomarkers, Tumor, Clinical Decision-Making, Genetics, Aging, Cancer, Prevention, Prostate Cancer, Urologic Diseases, 4.1 Discovery and preclinical testing of markers and technologies, Detection, screening and diagnosis, Clinical Sciences, Oncology and Carcinogenesis, Oncology & Carcinogenesis
Abstract

Purpose Guidelines are limited for genetic testing for prostate cancer (PCA). The goal of this conference was to develop an expert consensus-driven working framework for comprehensive genetic evaluation of inherited PCA in the multigene testing era addressing genetic counseling, testing, and genetically informed management. Methods An expert consensus conference was convened including key stakeholders to address genetic counseling and testing, PCA screening, and management informed by evidence review. Results Consensus was strong that patients should engage in shared decision making for genetic testing. There was strong consensus to test HOXB13 for suspected hereditary PCA, BRCA1/2 for suspected hereditary breast and ovarian cancer, and DNA mismatch repair genes for suspected Lynch syndrome. There was strong consensus to factor BRCA2 mutations into PCA screening discussions. BRCA2 achieved moderate consensus for factoring into early-stage management discussion, with stronger consensus in high-risk/advanced and metastatic setting. Agreement was moderate to test all men with metastatic castration-resistant PCA, regardless of family history, with stronger agreement to test BRCA1/2 and moderate agreement to test ATM to inform prognosis and targeted therapy. Conclusion To our knowledge, this is the first comprehensive, multidisciplinary consensus statement to address a genetic evaluation framework for inherited PCA in the multigene testing era. Future research should focus on developing a working definition of familial PCA for clinical genetic testing, expanding understanding of genetic contribution to aggressive PCA, exploring clinical use of genetic testing for PCA management, genetic testing of African American males, and addressing the value framework of genetic evaluation and testing men at risk for PCA-a clinically heterogeneous disease.

Published
2018

13. AR coactivators, CBP/p300, are critical mediators of DNA repair in prostate cancer

Author

Sardar, Sumaira, primary, McNair, Christopher M., additional, Ravindranath, Lakshmi, additional, Chand, Saswati N., additional, Yuan, Wei, additional, Bogdan, Denisa, additional, Welti, Jon, additional, Sharp, Adam, additional, Ryan, Natalie K., additional, Schiewer, Matthew J., additional, DeArment, Elise G., additional, Janas, Thomas, additional, Su, Xiaofeng A., additional, Butler, Lisa M., additional, de Bono, Johann S., additional, Frese, Kris, additional, Brooks, Nigel, additional, Pegg, Neil, additional, Knudsen, Karen E., additional, and Shafi, Ayesha A., additional

Published
2024
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15. Androgen Receptor Deregulation Drives Bromodomain-Mediated Chromatin Alterations in Prostate Cancer

Author

Urbanucci, Alfonso, Barfeld, Stefan J, Kytölä, Ville, Itkonen, Harri M, Coleman, Ilsa M, Vodák, Daniel, Sjöblom, Liisa, Sheng, Xia, Tolonen, Teemu, Minner, Sarah, Burdelski, Christoph, Kivinummi, Kati K, Kohvakka, Annika, Kregel, Steven, Takhar, Mandeep, Alshalalfa, Mohammed, Davicioni, Elai, Erho, Nicholas, Lloyd, Paul, Karnes, R Jeffrey, Ross, Ashley E, Schaeffer, Edward M, Griend, Donald J Vander, Knapp, Stefan, Corey, Eva, Feng, Felix Y, Nelson, Peter S, Saatcioglu, Fahri, Knudsen, Karen E, Tammela, Teuvo LJ, Sauter, Guido, Schlomm, Thorsten, Nykter, Matti, Visakorpi, Tapio, and Mills, Ian G

Subjects
Biological Sciences, Urologic Diseases, Prostate Cancer, Aging, Genetics, Cancer, 2.1 Biological and endogenous factors, Aetiology, ATPases Associated with Diverse Cellular Activities, Chromatin, Chromatin Assembly and Disassembly, DNA-Binding Proteins, Gene Expression Regulation, Neoplastic, Humans, Male, Neoplasm Proteins, Prostatic Neoplasms, Castration-Resistant, Protein Serine-Threonine Kinases, Receptors, Androgen, Transcription Factors, ATAD2, BRD2, BRD4, BROMO-10, androgen receptor, bromodomain inhibitor, castration-resistant prostate cancer, chromatin, Biochemistry and Cell Biology, Medical Physiology, Biological sciences
Abstract

Global changes in chromatin accessibility may drive cancer progression by reprogramming transcription factor (TF) binding. In addition, histone acetylation readers such as bromodomain-containing protein 4 (BRD4) have been shown to associate with these TFs and contribute to aggressive cancers including prostate cancer (PC). Here, we show that chromatin accessibility defines castration-resistant prostate cancer (CRPC). We show that the deregulation of androgen receptor (AR) expression is a driver of chromatin relaxation and that AR/androgen-regulated bromodomain-containing proteins (BRDs) mediate this effect. We also report that BRDs are overexpressed in CRPCs and that ATAD2 and BRD2 have prognostic value. Finally, we developed gene stratification signature (BROMO-10) for bromodomain response and PC prognostication, to inform current and future trials with drugs targeting these processes. Our findings provide a compelling rational for combination therapy targeting bromodomains in selected patients in which BRD-mediated TF binding is enhanced or modified as cancer progresses.

Published
2017

17. Potential Impact on Clinical Decision Making via a Genome-Wide Expression Profiling: A Case Report

Author

Kim, Hyun, Alshalalfa, Mohammed, Hoffman-Censits, Jean, Lallas, Costas D, Davicioni, Elai, Lin, Jianqing, Birbe, Ruth, Erho, Nicholas, Lehrer, Jonathan, Ashab, Hussam Al-Deen, Takhar, Mandeep, Olson, Anders, Lam, Lucia LC, Kelly, W Kevin, Knudsen, Karen E, Thangavel, Chellappagounder, Seiler, Roland, Feng, Felix Y, Schaeffer, Edward M, Trabulsi, Edouard J, Gomella, Leonard G, Hurwitz, Mark D, Dicker, Adam P, and Den, Robert B

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Cancer, Rare Diseases, Clinical Research, Health Services, Aging, Human Genome, Genetics, Urologic Diseases, Patient Safety, Clinical Trials and Supportive Activities, Prostate Cancer, Behavioral and Social Science, Biotechnology, Detection, screening and diagnosis, 4.2 Evaluation of markers and technologies, Prostate, Neuroendocrine, Genomics, Clinical sciences
Abstract

Management of men with prostate cancer is fraught with uncertainty as physicians and patients balance efficacy with potential toxicity and diminished quality of life. Utilization of genomics as a prognostic biomarker has improved the informed decision-making process by enabling more rationale treatment choices. Recently investigations have begun to determine whether genomic information from tumor transcriptome data can be used to impact clinical decision-making beyond prognosis. Here we discuss the potential of genomics to alter management of a patient who presented with high-risk prostate adenocarcinoma. We suggest that this information help selecting patients for advanced imaging, chemotherapies, or clinical trial.

Published
2016

19. Prospective study to define the clinical utility and benefit of Decipher testing in men following prostatectomy

Author

Marascio, Joseph, Spratt, Daniel E., Zhang, Jingbin, Trabulsi, Edouard J., Le, Tiffany, Sedzorme, Worlanyo Sosu, Beeler, Whitney H., Davicioni, Elai, Dabbas, Bashar, Lin, Daniel W., Gore, John L., Bloom, Matthew, Mann, Mark, Mark, J. Ryan, Calvaresi, Anne, Godwin, James L., McCue, Peter, Hurwitz, Mark D., Kelly, W. Kevin, Lallas, Costas D., Knudsen, Karen E., Gomella, Leonard G., Dicker, Adam P., and Den, Robert B.

Published
2020
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21. DNA-Repair Defects and Olaparib in Metastatic Prostate Cancer

Author

Mateo, Joaquin, Carreira, Suzanne, Sandhu, Shahneen, Miranda, Susana, Mossop, Helen, Perez-Lopez, Raquel, Nava Rodrigues, Daniel, Robinson, Dan, Omlin, Aurelius, Tunariu, Nina, Boysen, Gunther, Porta, Nuria, Flohr, Penny, Gillman, Alexa, Figueiredo, Ines, Paulding, Claire, Seed, George, Jain, Suneil, Ralph, Christy, Protheroe, Andrew, Hussain, Syed, Jones, Robert, Elliott, Tony, McGovern, Ursula, Bianchini, Diletta, Goodall, Jane, Zafeiriou, Zafeiris, Williamson, Chris T, Ferraldeschi, Roberta, Riisnaes, Ruth, Ebbs, Bernardette, Fowler, Gemma, Roda, Desamparados, Yuan, Wei, Wu, Yi-Mi, Cao, Xuhong, Brough, Rachel, Pemberton, Helen, A'Hern, Roger, Swain, Amanda, Kunju, Lakshmi P, Eeles, Rosalind, Attard, Gerhardt, Lord, Christopher J, Ashworth, Alan, Rubin, Mark A, Knudsen, Karen E, Feng, Felix Y, Chinnaiyan, Arul M, Hall, Emma, and de Bono, Johann S

Subjects
Genetics, Urologic Diseases, Human Genome, Prostate Cancer, Cancer, Clinical Research, 6.1 Pharmaceuticals, 6.2 Cellular and gene therapies, Evaluation of treatments and therapeutic interventions, 4.1 Discovery and preclinical testing of markers and technologies, Detection, screening and diagnosis, Adult, Aged, Anemia, Antineoplastic Agents, Ataxia Telangiectasia Mutated Proteins, DNA Repair, Drug Resistance, Neoplasm, Enzyme Inhibitors, Fatigue, Genes, BRCA2, Genes, Tumor Suppressor, Humans, Male, Middle Aged, Mutation, Neoplasm Metastasis, Phthalazines, Piperazines, Poly(ADP-ribose) Polymerase Inhibitors, Prostatic Neoplasms, Medical and Health Sciences, General & Internal Medicine
Abstract

BackgroundProstate cancer is a heterogeneous disease, but current treatments are not based on molecular stratification. We hypothesized that metastatic, castration-resistant prostate cancers with DNA-repair defects would respond to poly(adenosine diphosphate [ADP]-ribose) polymerase (PARP) inhibition with olaparib.MethodsWe conducted a phase 2 trial in which patients with metastatic, castration-resistant prostate cancer were treated with olaparib tablets at a dose of 400 mg twice a day. The primary end point was the response rate, defined either as an objective response according to Response Evaluation Criteria in Solid Tumors, version 1.1, or as a reduction of at least 50% in the prostate-specific antigen level or a confirmed reduction in the circulating tumor-cell count from 5 or more cells per 7.5 ml of blood to less than 5 cells per 7.5 ml. Targeted next-generation sequencing, exome and transcriptome analysis, and digital polymerase-chain-reaction testing were performed on samples from mandated tumor biopsies.ResultsOverall, 50 patients were enrolled; all had received prior treatment with docetaxel, 49 (98%) had received abiraterone or enzalutamide, and 29 (58%) had received cabazitaxel. Sixteen of 49 patients who could be evaluated had a response (33%; 95% confidence interval, 20 to 48), with 12 patients receiving the study treatment for more than 6 months. Next-generation sequencing identified homozygous deletions, deleterious mutations, or both in DNA-repair genes--including BRCA1/2, ATM, Fanconi's anemia genes, and CHEK2--in 16 of 49 patients who could be evaluated (33%). Of these 16 patients, 14 (88%) had a response to olaparib, including all 7 patients with BRCA2 loss (4 with biallelic somatic loss, and 3 with germline mutations) and 4 of 5 with ATM aberrations. The specificity of the biomarker suite was 94%. Anemia (in 10 of the 50 patients [20%]) and fatigue (in 6 [12%]) were the most common grade 3 or 4 adverse events, findings that are consistent with previous studies of olaparib.ConclusionsTreatment with the PARP inhibitor olaparib in patients whose prostate cancers were no longer responding to standard treatments and who had defects in DNA-repair genes led to a high response rate. (Funded by Cancer Research UK and others; ClinicalTrials.gov number, NCT01682772; Cancer Research UK number, CRUK/11/029.).

Published
2015

22. DNA-PKcs-Mediated Transcriptional Regulation Drives Prostate Cancer Progression and Metastasis

Author

Goodwin, Jonathan F, Kothari, Vishal, Drake, Justin M, Zhao, Shuang, Dylgjeri, Emanuela, Dean, Jeffry L, Schiewer, Matthew J, McNair, Christopher, Jones, Jennifer K, Aytes, Alvaro, Magee, Michael S, Snook, Adam E, Zhu, Ziqi, Den, Robert B, Birbe, Ruth C, Gomella, Leonard G, Graham, Nicholas A, Vashisht, Ajay A, Wohlschlegel, James A, Graeber, Thomas G, Karnes, R Jeffrey, Takhar, Mandeep, Davicioni, Elai, Tomlins, Scott A, Abate-Shen, Cory, Sharifi, Nima, Witte, Owen N, Feng, Felix Y, and Knudsen, Karen E

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Genetics, Cancer, 2.1 Biological and endogenous factors, Animals, Cell Line, Tumor, DNA-Activated Protein Kinase, DNA-Binding Proteins, Gene Expression Regulation, Neoplastic, Gene Regulatory Networks, Humans, Male, Mice, Molecular Sequence Data, Neoplasm Invasiveness, Neoplasm Transplantation, Nuclear Proteins, Prostatic Neoplasms, Receptors, Androgen, Neurosciences, Oncology & Carcinogenesis, Biochemistry and cell biology, Oncology and carcinogenesis
Abstract

Emerging evidence demonstrates that the DNA repair kinase DNA-PKcs exerts divergent roles in transcriptional regulation of unsolved consequence. Here, in vitro and in vivo interrogation demonstrate that DNA-PKcs functions as a selective modulator of transcriptional networks that induce cell migration, invasion, and metastasis. Accordingly, suppression of DNA-PKcs inhibits tumor metastases. Clinical assessment revealed that DNA-PKcs is significantly elevated in advanced disease and independently predicts for metastases, recurrence, and reduced overall survival. Further investigation demonstrated that DNA-PKcs in advanced tumors is highly activated, independent of DNA damage indicators. Combined, these findings reveal unexpected DNA-PKcs functions, identify DNA-PKcs as a potent driver of tumor progression and metastases, and nominate DNA-PKcs as a therapeutic target for advanced malignancies.

Published
2015

24. Prostate cancer

Author

Rebello, Richard J., Oing, Christoph, Knudsen, Karen E., Loeb, Stacy, Johnson, David C., Reiter, Robert E., Gillessen, Silke, Van der Kwast, Theodorus, and Bristow, Robert G.

Published
2021
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27. PCAT-1, a Long Noncoding RNA, Regulates BRCA2 and Controls Homologous Recombination in Cancer

Author

Prensner, John R, Chen, Wei, Iyer, Matthew K, Cao, Qi, Ma, Teng, Han, Sumin, Sahu, Anirban, Malik, Rohit, Wilder-Romans, Kari, Navone, Nora, Logothetis, Christopher J, Araujo, John C, Pisters, Louis L, Tewari, Ashutosh K, Canman, Christine E, Knudsen, Karen E, Kitabayashi, Naoki, Rubin, Mark A, Demichelis, Francesca, Lawrence, Theodore S, Chinnaiyan, Arul M, and Feng, Felix Y

Subjects
Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Genetics, Urologic Diseases, Prostate Cancer, Cancer, Biotechnology, Aetiology, 2.1 Biological and endogenous factors, 3' Untranslated Regions, Animals, Antineoplastic Agents, BRCA2 Protein, Cell Death, Cell Line, Tumor, DNA Damage, Gene Expression Regulation, Neoplastic, Humans, Male, Mice, Mice, SCID, Phthalazines, Piperazines, Poly (ADP-Ribose) Polymerase-1, Poly(ADP-ribose) Polymerase Inhibitors, Poly(ADP-ribose) Polymerases, Prostatic Neoplasms, RNA Interference, RNA, Long Noncoding, Recombinational DNA Repair, Xenograft Model Antitumor Assays, Oncology & Carcinogenesis, Biochemistry and cell biology, Oncology and carcinogenesis
Abstract

Impairment of double-stranded DNA break (DSB) repair is essential to many cancers. However, although mutations in DSB repair proteins are common in hereditary cancers, mechanisms of impaired DSB repair in sporadic cancers remain incompletely understood. Here, we describe the first role for a long noncoding RNA (lncRNA) in DSB repair in prostate cancer. We identify PCAT-1, a prostate cancer outlier lncRNA, which regulates cell response to genotoxic stress. PCAT-1 expression produces a functional deficiency in homologous recombination through its repression of the BRCA2 tumor suppressor, which, in turn, imparts a high sensitivity to small-molecule inhibitors of PARP1. These effects reflected a posttranscriptional repression of the BRCA2 3'UTR by PCAT-1. Our observations thus offer a novel mechanism of "BRCAness" in sporadic cancers.

Published
2014

28. 27-hydroxycholesterol and DNA damage repair: implication in prostate cancer

Author

Galvan, Gloria Cecilia, primary, Friedrich, Nadine A., additional, Das, Sanjay, additional, Daniels, James P., additional, Pollan, Sara, additional, Dambal, Shweta, additional, Suzuki, Ryusuke, additional, Sanders, Sergio E., additional, You, Sungyong, additional, Tanaka, Hisashi, additional, Lee, Yeon-Joo, additional, Yuan, Wei, additional, de Bono, Johann S., additional, Vasilevskaya, Irina, additional, Knudsen, Karen E., additional, Freeman, Michael R., additional, and Freedland, Stephen J., additional

Published
2023
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33. Master Transcription Factor Reprogramming Unleashes Selective Translation Promoting Castration Resistance and Immune Evasion in Lethal Prostate Cancer

Author

Santasusagna, Sandra, primary, Zhu, Shijia, additional, Jawalagatti, Vijayakumar, additional, Carceles-Cordon, Marc, additional, Ertel, Adam, additional, Garcia-Longarte, Saioa, additional, Song, Won-Min, additional, Fujiwara, Naoto, additional, Li, Peiyao, additional, Mendizabal, Isabel, additional, Petrylak, Daniel P., additional, Kelly, William Kevin, additional, Reddy, E. Premkumar, additional, Wang, Liguo, additional, Schiewer, Matthew J., additional, Lujambio, Amaia, additional, Karnes, Jeffrey, additional, Knudsen, Karen E., additional, Cordon-Cardo, Carlos, additional, Dong, Haidong, additional, Huang, Haojie, additional, Carracedo, Arkaitz, additional, Hoshida, Yujin, additional, Rodriguez-Bravo, Veronica, additional, and Domingo-Domenech, Josep, additional

Published
2023
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34. 27-hydroxycholesterol and DNA damage repair: implication in prostate cancer.

Author

Galvan, Gloria Cecilia, Friedrich, Nadine A., Das, Sanjay, Daniels, James P., Pollan, Sara, Dambal, Shweta, Suzuki, Ryusuke, Sanders, Sergio E., Sungyong You, Hisashi Tanaka, Yeon-Joo Lee, Wei Yuan, de Bono, Johann S., Vasilevskaya, Irina, Knudsen, Karen E., Freeman, Michael R., and Freedland, Stephen J.

Subjects
DNA repair, DNA damage, GENE expression, PROSTATE cancer, HOMOLOGOUS recombination, GENE targeting, ANDROGEN receptors
Abstract

Introduction: We previously reported that cholesterol homeostasis in prostate cancer (PC) is regulated by 27-hydroxycholesterol (27HC) and that CYP27A1, the enzyme that converts cholesterol to 27HC, is frequently lost in PCs. We observed that restoring the CYP27A1/27HC axis inhibited PC growth. In this study, we investigated the mechanism of 27HC-mediated anti-PC effects. Methods: We employed in vitro models and human transcriptomics data to investigate 27HC mechanism of action in PC. LNCaP (AR+) and DU145 (AR-) cells were treated with 27HC or vehicle. Transcriptome profiling was performed using the Affymetrix GeneChip™ microarray system. Differential expression was determined, and gene set enrichment analysis was done using the GSEA software with hallmark gene sets from MSigDB. Key changes were validated at mRNA and protein levels. Human PC transcriptomes from six datasets were analyzed to determine the correlation between CYP27A1 and DNA repair gene expression signatures. DNA damage was assessed via comet assays. Results: Transcriptome analysis revealed 27HC treatment downregulated Hallmark pathways related to DNA damage repair, decreased expression of FEN1 and RAD51, and induced "BRCAness" by downregulating genes involved in homologous recombination regulation in LNCaP cells. Consistently, we found a correlation between higher CYP27A1 expression (i.e., higher intracellular 27HC) and decreased expression of DNA repair gene signatures in castration-sensitive PC (CSPC) in human PC datasets. However, such correlation was less clear in metastatic castration-resistant PC (mCRPC). 27HC increased expression of DNA damage repair markers in PC cells, notably in AR+ cells, but no consistent effects in AR- cells and decreased expression in non-neoplastic prostate epithelial cells. While testing the clinical implications of this, we noted that 27HC treatment increased DNA damage in LNCaP cells via comet assays. Effects were reversible by adding back cholesterol, but not androgens. Finally, in combination with olaparib, a PARP inhibitor, we showed additive DNA damage effects. Discussion: These results suggest 27HC induces "BRCAness", a functional state thought to increase sensitivity to PARP inhibitors, and leads to increased DNA damage, especially in CSPC. Given the emerging appreciation that defective DNA damage repair can drive PC growth, future studies are needed to test whether 27HC creates a synthetic lethality to PARP inhibitors and DNA damaging agents in CSPC. [ABSTRACT FROM AUTHOR]

Published
2024
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36. Differential impact of RB status on E2F1 reprogramming in human cancer

Author

McNair, Christopher, Xu, Kexin, Mandigo, Amy C., Benelli, Matteo, Leiby, Benjamin, Rodrigues, Daniel, Lindberg, Johan, Gronberg, Henrik, Crespo, Mateus, De Laere, Bram, Dirix, Luc, Visakorpi, Tapio, Li, Fugen, Feng, Felix Y., de Bono, Johann, Demichelis, Francesca, Rubin, Mark A., Brown, Myles, and Knudsen, Karen E.

Subjects
Retinoblastoma -- Research -- Development and progression, Prostate cancer -- Development and progression -- Analysis -- Research, Transcription factors -- Physiological aspects, Health care industry
Abstract

The tumor suppressor protein retinoblastoma (RB) is mechanistically linked to suppression of transcription factor E2F1 -mediated cell cycle regulation. For multiple tumor types, loss of RB function is associated with poor clinical outcome. RB action is abrogated either by direct depletion or through inactivation of RB function; however, the basis for this selectivity is unknown. Here, analysis of tumor samples and cell-free DNA from patients with advanced prostate cancer showed that direct RB loss was the preferred pathway of disruption in human disease. While RB loss was associated with lethal disease, RB-deficient tumors had no proliferative advantage and exhibited downstream effects distinct from cell cycle control. Mechanistically, RB loss led to E2F1 cistrome expansion and different binding specificity, alterations distinct from those observed after functional RB inactivation. Additionally, identification of protumorigenic transcriptional networks specific to RB loss that were validated in clinical samples demonstrated the ability of RB loss to differentially reprogram E2F1 in human cancers. Together, these findings not only identify tumor-suppressive functions of RB that are distinct from cell cycle control, but also demonstrate that the molecular consequence of RB loss is distinct from RB inactivation. Thus, these studies provide insight into how RB loss promotes disease progression, and identify new nodes for therapeutic intervention., Introduction The function of the retinoblastoma tumor suppressor (RB) in preventing tumor development relies in large part on the capacity of this transcriptional corepressor to modulate E2F family transcription factor [...]

Published
2018
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37. Data from Novel Oncogenic Transcription Factor Cooperation in RB-Deficient Cancer

Author

Mandigo, Amy C., primary, Shafi, Ayesha A., primary, McCann, Jennifer J., primary, Yuan, Wei, primary, Laufer, Talya S., primary, Bogdan, Denisa, primary, Gallagher, Lewis, primary, Dylgjeri, Emanuela, primary, Semenova, Galina, primary, Vasilevskaya, Irina A., primary, Schiewer, Matthew J., primary, McNair, Chris M., primary, de Bono, Johann S., primary, and Knudsen, Karen E., primary

Published
2023
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38. Figure 3 from Novel Oncogenic Transcription Factor Cooperation in RB-Deficient Cancer

Author

Mandigo, Amy C., primary, Shafi, Ayesha A., primary, McCann, Jennifer J., primary, Yuan, Wei, primary, Laufer, Talya S., primary, Bogdan, Denisa, primary, Gallagher, Lewis, primary, Dylgjeri, Emanuela, primary, Semenova, Galina, primary, Vasilevskaya, Irina A., primary, Schiewer, Matthew J., primary, McNair, Chris M., primary, de Bono, Johann S., primary, and Knudsen, Karen E., primary

Published
2023
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39. Supplementary Figure Legends from Novel Oncogenic Transcription Factor Cooperation in RB-Deficient Cancer

Author

Mandigo, Amy C., primary, Shafi, Ayesha A., primary, McCann, Jennifer J., primary, Yuan, Wei, primary, Laufer, Talya S., primary, Bogdan, Denisa, primary, Gallagher, Lewis, primary, Dylgjeri, Emanuela, primary, Semenova, Galina, primary, Vasilevskaya, Irina A., primary, Schiewer, Matthew J., primary, McNair, Chris M., primary, de Bono, Johann S., primary, and Knudsen, Karen E., primary

Published
2023
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40. Figure 4 from Novel Oncogenic Transcription Factor Cooperation in RB-Deficient Cancer

Author

Mandigo, Amy C., primary, Shafi, Ayesha A., primary, McCann, Jennifer J., primary, Yuan, Wei, primary, Laufer, Talya S., primary, Bogdan, Denisa, primary, Gallagher, Lewis, primary, Dylgjeri, Emanuela, primary, Semenova, Galina, primary, Vasilevskaya, Irina A., primary, Schiewer, Matthew J., primary, McNair, Chris M., primary, de Bono, Johann S., primary, and Knudsen, Karen E., primary

Published
2023
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41. Figure 1 from Novel Oncogenic Transcription Factor Cooperation in RB-Deficient Cancer

Author

Mandigo, Amy C., primary, Shafi, Ayesha A., primary, McCann, Jennifer J., primary, Yuan, Wei, primary, Laufer, Talya S., primary, Bogdan, Denisa, primary, Gallagher, Lewis, primary, Dylgjeri, Emanuela, primary, Semenova, Galina, primary, Vasilevskaya, Irina A., primary, Schiewer, Matthew J., primary, McNair, Chris M., primary, de Bono, Johann S., primary, and Knudsen, Karen E., primary

Published
2023
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42. Figure 2 from Novel Oncogenic Transcription Factor Cooperation in RB-Deficient Cancer

Author

Mandigo, Amy C., primary, Shafi, Ayesha A., primary, McCann, Jennifer J., primary, Yuan, Wei, primary, Laufer, Talya S., primary, Bogdan, Denisa, primary, Gallagher, Lewis, primary, Dylgjeri, Emanuela, primary, Semenova, Galina, primary, Vasilevskaya, Irina A., primary, Schiewer, Matthew J., primary, McNair, Chris M., primary, de Bono, Johann S., primary, and Knudsen, Karen E., primary

Published
2023
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43. Data from Targeting the p300/CBP Axis in Lethal Prostate Cancer

Author

Welti, Jonathan, primary, Sharp, Adam, primary, Brooks, Nigel, primary, Yuan, Wei, primary, McNair, Christopher, primary, Chand, Saswati N., primary, Pal, Abhijit, primary, Figueiredo, Ines, primary, Riisnaes, Ruth, primary, Gurel, Bora, primary, Rekowski, Jan, primary, Bogdan, Denisa, primary, West, William, primary, Young, Barbara, primary, Raja, Meera, primary, Prosser, Amy, primary, Lane, Jordan, primary, Thomson, Stuart, primary, Worthington, Jenny, primary, Onions, Stuart, primary, Shannon, Jonathan, primary, Paoletta, Silvia, primary, Brown, Richard, primary, Smyth, Don, primary, Harbottle, Gareth W., primary, Gil, Veronica S., primary, Miranda, Susana, primary, Crespo, Mateus, primary, Ferreira, Ana, primary, Pereira, Rita, primary, Tunariu, Nina, primary, Carreira, Suzanne, primary, Neeb, Antje J., primary, Ning, Jian, primary, Swain, Amanda, primary, Taddei, David, primary, Schiewer, Matthew J., primary, Knudsen, Karen E., primary, Pegg, Neil, primary, and de Bono, Johann S., primary

Published
2023
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45. Supplementary Figures 1-9 from Dual Roles of PARP-1 Promote Cancer Growth and Progression

Author

Schiewer, Matthew J., primary, Goodwin, Jonathan F., primary, Han, Sumin, primary, Brenner, J. Chad, primary, Augello, Michael A., primary, Dean, Jeffry L., primary, Liu, Fengzhi, primary, Planck, Jamie L., primary, Ravindranathan, Preethi, primary, Chinnaiyan, Arul M., primary, McCue, Peter, primary, Gomella, Leonard G., primary, Raj, Ganesh V., primary, Dicker, Adam P., primary, Brody, Jonathan R., primary, Pascal, John M., primary, Centenera, Margaret M., primary, Butler, Lisa M., primary, Tilley, Wayne D., primary, Feng, Felix Y., primary, and Knudsen, Karen E., primary

Published
2023
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