Your search keyword '"Joshi J. Alumkal"' showing total 256 results

1. Survival by first‐line therapy and prognostic group among men with metastatic castration‐resistant prostate cancer

Author

Megan E. V. Caram, Kyle Kumbier, Phoebe A. Tsao, Jennifer Burns, Jordan B. Sparks, Kristian D. Stensland, Zachery R. Reichert, Joshi J. Alumkal, Brent K. Hollenbeck, Vahakn Shahinian, Alexander Tsodikov, and Ted A. Skolarus

Subjects

novel therapies, prognosis, prostate cancer, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Introduction Metastatic castration‐resistant prostate cancer (mCRPC) is a heterogeneous disease with prognoses varying from months to years at time of castration‐resistant diagnosis. Optimal first‐line therapy for those with different prognoses is unknown. Methods We conducted a retrospective cohort study of men in a national healthcare delivery system receiving first‐line therapy for mCRPC (abiraterone, enzalutamide, docetaxel, or ketoconazole) from 2010 to 2017, with follow‐up through 2019. Using commonly drawn prognostic labs at start of mCRPC therapy (hemoglobin, albumin, and alkaline phosphatase), we categorized men into favorable, intermediate, or poor prognostic groups depending on whether they had none, one to two, or all three laboratory values worse than designated laboratory cutoffs. We used Kaplan–Meier methods to examine prostate specific antigen (PSA) progression‐free and overall survival (OS) according to prognostic group and first‐line therapy, and multivariable cox regression to determine variables associated with survival outcomes. Results Among 4135 patients, median PSA progression‐free survival (PFS) was 6.9 months (95% confidence interval [CI] 6.6–7.3), and median OS 18.8 months (95% CI 18.0–19.6), ranging from 5.7 months (95% CI 4.8–7.0) in the poor prognosis group to 31.3 months (95% CI 29.7–32.9) in the favorable group. OS was similar regardless of initial treatment received for favorable and intermediate groups, but worse for those in the poor prognostic group who received ketoconazole (adjusted hazard ratio 2.07, 95% CI 1.2–3.6). PSA PFS was worse for those who received ketoconazole compared to abiraterone across all prognostic groups (favorable HR 1.76, 95% CI 1.34–2.31; intermediate HR 1.78, 95% CI 1.41–2.25; poor HR 8.01, 95% CI 2.93–21.9). Conclusion Commonly drawn labs at mCRPC treatment start may aid in predicting survival and response to therapies, potentially informing discussions with care teams. First‐line treatment selection impacts disease progression for all men with mCRPC regardless of prognostic group, but impacted OS only for men with poor prognosis at treatment start.

Published

2024

2. LSD1 promotes prostate cancer reprogramming by repressing TP53 signaling independently of its demethylase function

Author

Anbarasu Kumaraswamy, Zhi Duan, Diana Flores, Chao Zhang, Archana Sehrawat, Ya-Mei Hu, Olivia A. Swaim, Eva Rodansky, William K. Storck, Joshua A. Kuleape, Karan Bedi, Rahul Mannan, Xiao-Ming Wang, Aaron Udager, Visweswaran Ravikumar, Armand Bankhead III, Ilsa Coleman, John K. Lee, Colm Morrissey, Peter S. Nelson, Arul M. Chinnaiyan, Arvind Rao, Zheng Xia, Joel A. Yates, and Joshi J. Alumkal

Subjects

Oncology, Medicine

Abstract

Lysine-specific demethylase 1 (LSD1) is a histone demethylase that promotes stemness and cell survival in cancers such as prostate cancer. Most prostate malignancies are adenocarcinomas with luminal differentiation. However, some tumors undergo cellular reprogramming to a more lethal subset termed neuroendocrine prostate cancer (NEPC) with neuronal differentiation. The frequency of NEPC is increasing since the widespread use of potent androgen receptor signaling inhibitors. Currently, there are no effective treatments for NEPC. We previously determined that LSD1 promotes survival of prostate adenocarcinoma tumors. However, the role of LSD1 in NEPC is unknown. Here, we determined that LSD1 is highly upregulated in NEPC versus adenocarcinoma patient tumors. LSD1 suppression with RNAi or allosteric LSD1 inhibitors — but not catalytic inhibitors — reduced NEPC cell survival. RNA-Seq analysis revealed that LSD1 represses pathways linked to luminal differentiation, and TP53 was the top reactivated pathway. We confirmed that LSD1 suppressed the TP53 pathway by reducing TP53 occupancy at target genes while LSD1’s catalytic function was dispensable for this effect. Mechanistically, LSD1 inhibition disrupted LSD1-HDAC interactions, increasing histone acetylation at TP53 targets. Finally, LSD1 inhibition suppressed NEPC tumor growth in vivo. These findings suggest that blocking LSD1’s noncatalytic function may be a promising treatment strategy for NEPC.

Published

2023

3. Transcriptional profiling of matched patient biopsies clarifies molecular determinants of enzalutamide-induced lineage plasticity

Author

Thomas C. Westbrook, Xiangnan Guan, Eva Rodansky, Diana Flores, Chia Jen Liu, Aaron M. Udager, Radhika A. Patel, Michael C. Haffner, Ya-Mei Hu, Duanchen Sun, Tomasz M. Beer, Adam Foye, Rahul Aggarwal, David A. Quigley, Jack F. Youngren, Charles J. Ryan, Martin Gleave, Yuzhuo Wang, Jiaoti Huang, Ilsa Coleman, Colm Morrissey, Peter S. Nelson, Christopher P. Evans, Primo Lara, Robert E. Reiter, Owen Witte, Matthew Rettig, Christopher K. Wong, Alana S. Weinstein, Vlado Uzunangelov, Josh M. Stuart, George V. Thomas, Felix Y. Feng, Eric J. Small, Joel A. Yates, Zheng Xia, and Joshi J. Alumkal

Subjects

Science

Abstract

Lineage plasticity is increasingly recognized as an emergent resistance mechanism after treatment with androgen receptor signalling inhibitors. To understand determinants of resistance, the authors analyzed the transcriptomes of patient tumor biopsies before enzalutamide treatment and at progression and identified a gene expression program associated with lineage plasticity risk and poor outcomes.

Published

2022

4. The Role of Epigenetic Change in Therapy-Induced Neuroendocrine Prostate Cancer Lineage Plasticity

Author

William K. Storck, Allison M. May, Thomas C. Westbrook, Zhi Duan, Colm Morrissey, Joel A. Yates, and Joshi J. Alumkal

Subjects

Neuroendocrine prostate cancer (NEPC), Lineage plasticity, transdifferentiation, Androgen Receptor (AR), epigenetics, Diseases of the endocrine glands. Clinical endocrinology, RC648-665

Abstract

The androgen receptor (AR) signaling pathway is critical for growth and differentiation of prostate cancer cells. For that reason, androgen deprivation therapy with medical or surgical castration is the principal treatment for metastatic prostate cancer. More recently, new potent AR signaling inhibitors (ARSIs) have been developed. These drugs improve survival for men with metastatic castration-resistant prostate cancer (CRPC), the lethal form of the disease. However, ARSI resistance is nearly universal. One recently appreciated resistance mechanism is lineage plasticity or switch from an AR-driven, luminal differentiation program to an alternate differentiation program. Importantly, lineage plasticity appears to be increasing in incidence in the era of new ARSIs, strongly implicating AR suppression in this process. Lineage plasticity and shift from AR-driven tumors occur on a continuum, ranging from AR-expressing tumors with low AR activity to AR-null tumors that have activation of alternate differentiation programs versus the canonical luminal program found in AR-driven tumors. In many cases, AR loss coincides with the activation of a neuronal program, most commonly exemplified as therapy-induced neuroendocrine prostate cancer (t-NEPC). While genetic events clearly contribute to prostate cancer lineage plasticity, it is also clear that epigenetic events—including chromatin modifications and DNA methylation—play a major role. Many epigenetic factors are now targetable with drugs, establishing the importance of clarifying critical epigenetic factors that promote lineage plasticity. Furthermore, epigenetic marks are readily measurable, demonstrating the importance of clarifying which measurements will help to identify tumors that have undergone or are at risk of undergoing lineage plasticity. In this review, we discuss the role of AR pathway loss and activation of a neuronal differentiation program as key contributors to t-NEPC lineage plasticity. We also discuss new epigenetic therapeutic strategies to reverse lineage plasticity, including those that have recently entered clinical trials.

Published

2022

5. Alternative splicing of LSD1+8a in neuroendocrine prostate cancer is mediated by SRRM4

Author

Daniel J. Coleman, David A. Sampson, Archana Sehrawat, Anbarasu Kumaraswamy, Duanchen Sun, Yuzhuo Wang, Jacob Schwartzman, Joshua Urrutia, Ahn R. Lee, Ilsa M. Coleman, Peter S. Nelson, Xuesen Dong, Colm Morrissey, Eva Corey, Zheng Xia, Joel A. Yates, and Joshi J. Alumkal

Subjects

Neuroendocrine prostate cancer, LSD1, LSD1+8a, SRRM4, Epigenetics, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Neuroendocrine prostate cancer (NEPC) is the most virulent form of prostate cancer. Importantly, our recent work examining metastatic biopsy samples demonstrates NEPC is increasing in frequency. In contrast to prostate adenocarcinomas that express a luminal gene expression program, NEPC tumors express a neuronal gene expression program. Despite this distinction, the diagnosis of NEPC is often challenging, demonstrating an urgent need to identify new biomarkers and therapeutic targets. Our prior work demonstrated that the histone demethylase LSD1 (KDM1A) is important for survival of prostate adenocarcinomas, but little was known about LSD1’s role in NEPC. Recently, a neural-specific transcript variant of LSD1—LSD1+8a—was discovered and demonstrated to activate neuronal gene expression in neural cells. The splicing factor SRRM4 was previously shown to promote LSD1+8a splicing in neuronal cells, and SRRM4 promotes NEPC differentiation and cell survival. Therefore, we sought to determine if LSD1+8a might play a role in NEPC and whether LSD1+8a splicing was linked to SRRM4. To investigate a potential role for LSD1+8a in NEPC, we examined a panel of prostate adenocarcinoma and NEPC patient-derived xenografts and metastatic biopsies. LSD1+8a was expressed exclusively in NEPC samples and correlated significantly with elevated expression of SRRM4. Using SRRM4-overexpressing cell lines, we determined that SRRM4 mediates alternative splicing of LSD1+8a. Finally, using gain of function studies, we confirmed that LSD1+8a and SRRM4 co-regulate target genes distinct from canonical LSD1. Our findings suggest further study of the interplay between SRRM4 and LSD1+8a and mechanisms by which LSD1+8a regulates gene expression in NEPC is warranted.

Published

2020

6. Randomized, Open-Label Phase 2 Study of Apalutamide plus Androgen Deprivation Therapy versus Apalutamide Monotherapy versus Androgen Deprivation Monotherapy in Patients with Biochemically Recurrent Prostate Cancer

Author

Rahul Aggarwal, Joshi J. Alumkal, Russell Z. Szmulewitz, Celestia S. Higano, Alan H. Bryce, Angela Lopez-Gitlitz, Sharon A. McCarthy, Branko Miladinovic, Kelly McQuarrie, Shibu Thomas, Ke Zhang, and Eric J. Small

Subjects

Diseases of the genitourinary system. Urology, RC870-923, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Purpose. This randomized phase 2 study sought to assess the treatment effect of a finite duration of apalutamide with and without androgen deprivation therapy (ADT) in biochemically recurrent prostate cancer (BCR PC). Materials and Methods. Patients with BCR PC after primary definitive therapy and prostate-specific antigen (PSA) doubling time ≤12 months were randomized to open-label apalutamide (240 mg/d) alone, apalutamide plus ADT, or ADT alone (1 : 1:1 ratio) for 12 months followed by a 12-month observation period (NCT01790126). Mean changes from baseline in Functional Assessment of Cancer Therapy-Prostate (FACT-P) at 12 months (primary endpoint) and other prespecified assessments of health-related quality of life (HRQoL), PSA nadir, time to PSA progression, time to testosterone recovery, recovered testosterone >150 ng/dL without PSA progression at 24 months, and molecular markers were evaluated. Results. In 90 enrolled patients (apalutamide plus ADT (n = 31), apalutamide (n = 29), ADT (n = 30)), FACT-P at 12 months was not significantly different between apalutamide, ADT and apalutamide, and ADT groups. Addition of apalutamide to ADT prolonged time to PSA progression but this change did not reach statistical significance (hazard ratio (HR): 0.56, 95% confidence interval (CI): 0.23–1.36, P=0.196); time to testosterone recovery was similar in the ADT-containing groups. In apalutamide plus ADT, apalutamide, and ADT groups, 37.9%, 37.0%, and 19.2% of patients, respectively, had testosterone >150 ng/dL at 24 months without confirmed PSA progression. Of the few biomarkers expressed in blood, EPHA3 was significantly associated with shorter time to PSA progression (P=0.02) in the overall population. Conclusions. HRQoL was similar in patients treated with apalutamide alone, ADT alone, or their combination, although apalutamide plus ADT did not demonstrate statistically significant noninferiority in change from baseline in overall HRQoL. The aggregated efficacy and safety outcomes support further evaluation of apalutamide plus ADT in BCR PC.

Published

2022

7. Implementing a comprehensive translational oncology platform: from molecular testing to actionability

Author

Zahi I. Mitri, Swapnil Parmar, Brett Johnson, Annette Kolodzie, Jamie M. Keck, Max Morris, Alexander R. Guimaraes, Brooke R. Beckett, Uma Borate, Charles D. Lopez, Kathleen A. Kemmer, Joshi J. Alumkal, Tomasz M. Beer, Christopher L. Corless, Gordon B. Mills, Joe W. Gray, and Raymond C. Bergan

Subjects

Precision oncology, Translational research, Targeted therapy, Biomarkers, Clinical trials, Medicine

Abstract

Abstract Background In order to establish the workflows required to implement a real-time process involving multi-omic analysis of patient samples to support precision-guided therapeutic intervention, a tissue acquisition and analysis trial was implemented. This report describes our findings to date, including the frequency with which mutational testing led to precision-guided therapy and outcome for those patients. Methods Eligible patients presenting to Oregon Health and Science University Knight Cancer Institute were enrolled on the study. Patients with biopsy proven metastatic or locally advanced unresectable prostate cancer, breast cancer, pancreatic adenocarcinoma, or refractory acute myelogenous leukemia receiving standard of care therapy were eligible. Metastatic site biopsies were collected and analyzed using the Knight Diagnostic Lab GeneTrails comprehensive solid tumor panel (124 genes). CLIA certified genomic information was made available to the treating physician. Results Between 1/26/2017 and 5/30/2018, 38 patients were enrolled, with 28 successfully undergoing biopsy. Of these, 25 samples yielded sufficient tumor for analysis. The median biopsy cellularity and number of cores collected were 70% (15–90%) and 5 (2–20), respectively. No procedure-related complications occurred. GeneTrails analysis revealed that 22 of 25 (88%) tumor samples harbored at least one potentially actionable mutation, and 18 (72%) samples harbored 2 or more potentially actionable mutations. The most common genetic alterations identified involved: DNA damage repair genes, cell cycle regulating genes, PIK3CA/Akt/mTOR pathway, and FGF gene family. To date, CLIA certified genomic results were used by treating physicians for precision-guided therapy in 5 (23%) patients. Conclusion We report the feasibility of real-time tissue acquisition and analysis to support a successful translational oncology platform. The workflow will provide the foundation to improve access and accrual to biomarker driven precision oncology trials.

Published

2018

8. Multi-Omics Analyses Detail Metabolic Reprogramming in Lipids, Carnitines, and Use of Glycolytic Intermediates between Prostate Small Cell Neuroendocrine Carcinoma and Prostate Adenocarcinoma

Author

Bei Gao, Hui-Wen Lue, Jennifer Podolak, Sili Fan, Ying Zhang, Archana Serawat, Joshi J. Alumkal, Oliver Fiehn, and George V. Thomas

Subjects

oxygen consumption rate, extracellular acidification rate, hydrophilic interaction liquid chromatography (HILIC), N-Myc, Microbiology, QR1-502

Abstract

As the most common cancer in men, prostate cancer is molecularly heterogeneous. Contributing to this heterogeneity are the poorly understood metabolic adaptations of the two main types of prostate cancer, i.e., adenocarcinoma and small cell neuroendocrine carcinoma (SCNC), the latter being more aggressive and lethal. Using transcriptomics, untargeted metabolomics and lipidomics profiling on LASCPC-01 (prostate SCNC) and LNCAP (prostate adenocarcinoma) cell lines, we found significant differences in the cellular phenotypes of the two cell lines. Gene set enrichment analysis on the transcriptomics data showed 62 gene sets were upregulated in LASCPC-01, while 112 gene sets were upregulated in LNCAP. ChemRICH analysis on metabolomics and lipidomics data revealed a total of 25 metabolite clusters were significantly different. LASCPC-01 exhibited a higher glycolytic activity and lower levels of triglycerides, while the LNCAP cell line showed increases in one-carbon metabolism as an exit route of glycolytic intermediates and a decrease in carnitine, a mitochondrial lipid transporter. Our findings pinpoint differences in prostate neuroendocrine carcinoma versus prostate adenocarcinoma that could lead to new therapeutic targets in each type.

Published

2019

9. Metastatic prostate cancer diagnosed by fine‐needle aspiration: Contemporary cytopathologic and biomarker assessment with clinical correlates

Author

Richard L. Cantley, Xiaoming Wang, Zachery R. Reichert, Arul M. Chinnaiyan, Rahul Mannan, Xuhong Cao, Daniel E. Spratt, Ulka N. Vaishampayan, Joshi J. Alumkal, Todd M. Morgan, Ganesh Palapattu, Matthew S. Davenport, Liron Pantanowitz, and Rohit Mehra

Subjects

Cancer Research, Oncology

Abstract

The diagnosis of metastatic prostatic cancer (MPC) by fine needle aspiration (FNA) can usually be rendered by typical cytomorphologic and immunohistochemical (IHC) features. However, MPC diagnosis may be complicated by transformation to atypical phenotypes such as small cell carcinoma, typically under pressure from androgen deprivation therapy (ADT). Predictive and prognostic biomarkers can also be assessed by IHC. This study illustrates how careful assessment of cytologic and biomarker features may provide therapeutic and prognostic information in MPC.We reviewed our anatomic pathology archives for MPC diagnosed by FNA from January 2014 to June 2021. Clinical histories, cytology slides, and cell blocks were reviewed. Extensive IHC biomarker workup was performed, including markers of prostate lineage, cell-cycle dysfunction, Ki-67, neuroendocrine markers, PDL1, and androgen receptor splice variant 7. Cases were reclassified into three categories: conventional type, intermediary type, and high-grade neuroendocrine carcinoma (HGNC).Eighteen patients were identified. Twelve had conventional MPC, including six of six ADT-naive patients. Six of twelve (50%) with prior ADT were reclassified as intermediary or HGNC. Four intermediary cases included two with squamous differentiation and two with pro-proliferative features. Two HGNC cases had typical small cell carcinoma cytomorphology. Expression of PDL1 was identified in two cases and ARv7 in three cases. Five of five intermediary and HGNC patients died of disease versus six of eleven with with conventional type.Aggressive cytomorphologic variants were commonly identified in patients with prior ADT. Identification of nonconventional cytomorphology and increased proliferation can provide important prognostic information. Recognition of these changes is important for an accurate diagnosis, and the identification of high-grade variants can affect therapeutic decision-making. Clinically actionable biomarkers such as PDL1 and ARv7 can be assessed by IHC.

Published

2022

10. Supplementary Table 2 from Whole-Genome and Transcriptional Analysis of Treatment-Emergent Small-Cell Neuroendocrine Prostate Cancer Demonstrates Intraclass Heterogeneity

Author

Eric J. Small, Joshi J. Alumkal, Felix Y. Feng, Primo N. Lara, Christopher P. Evans, Kim N. Chi, Paul Lloyd, Denise Playdle, Adam Foye, George V. Thomas, Martin E. Gleave, Rob E. Reiter, Matthew B. Rettig, Tomasz M. Beer, Li Zhang, Jiaoti Huang, David A. Quigley, and Rahul R. Aggarwal

Abstract

Supplementary Table 2. Clinical Characteristics of the Evaluable Paired Biopsy Cohort

Published

2023

11. Supplementary Data from Modeling Androgen Deprivation Therapy–Induced Prostate Cancer Dormancy and Its Clinical Implications

Author

Yuzhuo Wang, Colin Collins, Martin Gleave, Adam G. Sowalsky, Joshi J. Alumkal, Steven P. Balk, Mary-Ellen Taplin, Rebecca Silver, Anne Haegert, Rebecca Wu, Xinpei Ci, Jun Hao, Anson T. Ku, Scott Wilkinson, Yingqiang Sun, Nelson K.Y. Wong, Dong Lin, Yen-yi Lin, Fan Mo, Hui Xue, and Xin Dong

Abstract

Supplementary Data from Modeling Androgen Deprivation Therapy–Induced Prostate Cancer Dormancy and Its Clinical Implications

Published

2023

12. Supplementary Table 1 from Whole-Genome and Transcriptional Analysis of Treatment-Emergent Small-Cell Neuroendocrine Prostate Cancer Demonstrates Intraclass Heterogeneity

Author

Eric J. Small, Joshi J. Alumkal, Felix Y. Feng, Primo N. Lara, Christopher P. Evans, Kim N. Chi, Paul Lloyd, Denise Playdle, Adam Foye, George V. Thomas, Martin E. Gleave, Rob E. Reiter, Matthew B. Rettig, Tomasz M. Beer, Li Zhang, Jiaoti Huang, David A. Quigley, and Rahul R. Aggarwal

Abstract

Supplementary Table 1. Clinical Characteristics of the Whole Genome Sequencing Cohort

Published

2023

13. Data from Whole-Genome and Transcriptional Analysis of Treatment-Emergent Small-Cell Neuroendocrine Prostate Cancer Demonstrates Intraclass Heterogeneity

Author

Eric J. Small, Joshi J. Alumkal, Felix Y. Feng, Primo N. Lara, Christopher P. Evans, Kim N. Chi, Paul Lloyd, Denise Playdle, Adam Foye, George V. Thomas, Martin E. Gleave, Rob E. Reiter, Matthew B. Rettig, Tomasz M. Beer, Li Zhang, Jiaoti Huang, David A. Quigley, and Rahul R. Aggarwal

Abstract

Therapeutic resistance in metastatic castration-resistant prostate cancer (mCRPC) can be accompanied by treatment-emergent small-cell neuroendocrine carcinoma (t-SCNC), a morphologically distinct subtype. We performed integrative whole-genome and -transcriptome analysis of mCRPC tumor biopsies including paired biopsies after progression, and multiple samples from the same individual. t-SCNC was significantly less likely to have amplification of AR or an intergenic AR-enhancer locus, and demonstrated lower expression of AR and its downstream transcriptional targets. Genomic and transcriptional hallmarks of t-SCNC included biallelic loss of RB1, elevated expression levels of CDKN2A and E2F1, and loss of expression of the AR and AR-responsive genes including TMPRSS2 and NKX3-1. We identified three tumors that converted from adenocarcinoma to t-SCNC and demonstrate spatial and temporal intrapatient heterogeneity of metastatic tumors harboring adenocarcinoma, t-SCNC, or mixed expression phenotypes, with implications for treatment strategies in which dual targeting of adenocarcinoma and t-SCNC phenotypes may be necessary.Implications:The t-SCNC phenotype is characterized by lack of AR enhancer gain and loss of RB1 function, and demonstrates both interindividual and intraindividual heterogeneity.Visual Overview: http://mcr.aacrjournals.org/content/molcanres/17/6/1235/F1.large.jpg.

Published

2023

14. Supplementary Tables 1 through 3, Supplementary Figures 1 through 7, and Supplementary Methods from Analysis of Circulating Cell-Free DNA Identifies Multiclonal Heterogeneity of BRCA2 Reversion Mutations Associated with Resistance to PARP Inhibitors

Author

Felix Y. Feng, Eric J. Small, Alan Ashworth, Tomasz M. Beer, Jack Youngren, Charles Ryan, Christopher J. Lord, Karen Knudsen, Scott Tomlins, George Thomas, Colin Pritchard, Morgan Diolaiti, Rajdeep Das, Matti Annala, Kevin Beja, Jacob Schwartzman, Eric Lu, Won Kim, Rahul Aggarwal, Paul Lloyd, Adam Foye, Vishal Kothari, Alexander W. Wyatt, Joshi J. Alumkal, and David Quigley

Abstract

Supplementary Table S1: Patient 1 reversion alleles. Supplementary Table 2: DNA read identifiers supporting reversion alleles. Supplementary Table S3: Gene targets of the SeqCap library used for cfDNA sequencing. Supplementary Figure S1: Frequent loss of heterozygosity in Patient 1's tumor DNA. Supplementary Figure S2: A single copy of chromosome 13 at the BRCA2 locus is present in Patient 1's tumor DNA. Supplementary Figure S3: Mutation signature three is present in patient 1's solid tumor. Supplementary Figure S4: A single copy of chromosome 13 at the BRCA2 locus is present in Patient 2's tumor DNA. Supplementary Figure S5: Patient 2's DNA coverage depth at residue 259. Supplementary Figure S6: Nucleotide and inferred protein sequences for patient 2's reversion alleles. Supplementary Figure S7: Reversion indels were significantly longer than the background distribution of indels. Supplementary Methods.

Published

2023

15. Modeling Androgen Deprivation Therapy–Induced Prostate Cancer Dormancy and Its Clinical Implications

Author

Xin Dong, Hui Xue, Fan Mo, Yen-yi Lin, Dong Lin, Nelson K.Y. Wong, Yingqiang Sun, Scott Wilkinson, Anson T. Ku, Jun Hao, Xinpei Ci, Rebecca Wu, Anne Haegert, Rebecca Silver, Mary-Ellen Taplin, Steven P. Balk, Joshi J. Alumkal, Adam G. Sowalsky, Martin Gleave, Colin Collins, and Yuzhuo Wang

Subjects

Male, Mice, Prostatic Neoplasms, Castration-Resistant, Cancer Research, Oncology, Androgen Receptor Antagonists, Androgens, Animals, Humans, Prostatic Neoplasms, Androgen Antagonists, Neoplasm Recurrence, Local, Molecular Biology

Abstract

Treatment-induced tumor dormancy is a state in cancer progression where residual disease is present but remains asymptomatic. Dormant cancer cells are treatment-resistant and responsible for cancer recurrence and metastasis. Prostate cancer treated with androgen-deprivation therapy (ADT) often enters a dormant state. ADT-induced prostate cancer dormancy remains poorly understood due to the challenge in acquiring clinical dormant prostate cancer cells and the lack of representative models. In this study, we aimed to develop clinically relevant models for studying ADT-induced prostate cancer dormancy. Dormant prostate cancer models were established by castrating mice bearing patient-derived xenografts (PDX) of hormonal naïve or sensitive prostate cancer. Dormancy status and tumor relapse were monitored and evaluated. Paired pre- and postcastration (dormant) PDX tissues were subjected to morphologic and transcriptome profiling analyses. As a result, we established eleven ADT-induced dormant prostate cancer models that closely mimicked the clinical courses of ADT-treated prostate cancer. We identified two ADT-induced dormancy subtypes that differed in morphology, gene expression, and relapse rates. We discovered transcriptomic differences in precastration PDXs that predisposed the dormancy response to ADT. We further developed a dormancy subtype-based, predisposed gene signature that was significantly associated with ADT response in hormonal naïve prostate cancer and clinical outcome in castration-resistant prostate cancer treated with ADT or androgen-receptor pathway inhibitors. Implications: We have established highly clinically relevant PDXs of ADT-induced dormant prostate cancer and identified two dormancy subtypes, leading to the development of a novel predicative gene signature that allows robust risk stratification of patients with prostate cancer to ADT or androgen-receptor pathway inhibitors.

Published

2022

16. Supplementary Table S5 from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Author

Joshi J. Alumkal, Zheng Xia, Joel A. Yates, Eric Campeau, Sanjay Lakhotia, Sarah Attwell, Emily M. Gesner, Arvind Rao, Armand Bankhead, Daniel E. Spratt, Eric J. Small, Felix Y. Feng, Wassim Abida, Rahul Aggarwal, Jonathan Z. Sexton, Samuel K. Handelman, Eva Corey, Peter S. Nelson, Ilsa M. Coleman, Jared M. Lucas, Colm Morrissey, Mark P. Labrecque, Himisha Beltran, Chao Zhang, Jacob A. Schwartzman, Joshua A. Urrutia, Eva S. Rodansky, Anbarasu Kumaraswamy, Xiangnan Guan, David Sampson, Daniel J. Coleman, Chelsea Jenkins, Katherine Welker Leng, William K. Storck, Duanchen Sun, and Dae-Hwan Kim

Abstract

Supplementary Table S5 from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Published

2023

17. Supplementary Table 2 from A Phase Ib/IIa Study of the Pan-BET Inhibitor ZEN-3694 in Combination with Enzalutamide in Patients with Metastatic Castration-resistant Prostate Cancer

Author

Joshi J. Alumkal, Wassim Abida, Eric J. Small, Felix Y. Feng, Sanjay Lakhotia, Lisa Bauman, Margo Snyder, Karen Norek, Sarah Attwell, Eric Campeau, Elisabeth I. Heath, Allan J. Pantuck, David M. Nanus, Michael T. Schweizer, and Rahul R. Aggarwal

Abstract

Supplementary Table 2

Published

2023

18. Figure S1 from Copy Number Loss of 17q22 Is Associated with Enzalutamide Resistance and Poor Prognosis in Metastatic Castration-Resistant Prostate Cancer

Author

Joshi J. Alumkal, Zheng Xia, Eric J. Small, Felix Y. Feng, Joshua M. Stuart, Alana S. Weinstein, Jack Youngren, William S. Chen, Adam Foye, David A. Quigley, Rahul R. Aggarwal, Jiaoti Huang, George V. Thomas, Tomasz M. Beer, Martin Gleave, Primo Lara, Christopher P. Evans, Matthew Rettig, Robert Evan Reiter, Joshua A. Urrutia, Eric Lu, Duanchen Sun, and Xiangnan Guan

Abstract

Figure S1 shows that copy number alterations of well-described prostate cancer tumor suppressor genes are not different between enzalutamide-naïve and -resistant tumors.

Published

2023

19. Data from Autoantibody Landscape in Patients with Advanced Prostate Cancer

Author

Felix Y. Feng, John C. Shon, David Y. Oh, Antoni Ribas, Patrick S. Daugherty, Eric J. Small, Rahul Aggarwal, Alan Ashworth, Joshi J. Alumkal, Robert E. Reiter, Kim N. Chi, Primo Lara, Christopher P. Evans, Martin Gleave, Matthew Rettig, Tomasz M. Beer, Jonathan Chou, David A. Quigley, Martin Sjöström, Shuang G. Zhao, Meng Zhang, Ivan Perez Garcilazo, Ignacio Baselga Carretero, Adam Foye, Minlu Zhang, Raunak Shrestha, Agustin Vega-Crespo, Kathy Kamath, Rebecca Waitz, Winston A. Haynes, and William S. Chen

Abstract

Purpose:Autoantibody responses in cancer are of great interest, as they may be concordant with T-cell responses to cancer antigens or predictive of response to cancer immunotherapies. Thus, we sought to characterize the antibody landscape of metastatic castration-resistant prostate cancer (mCRPC).Experimental Design:Serum antibody epitope repertoire analysis (SERA) was performed on patient serum to identify tumor-specific neoepitopes. Somatic mutation–specific neoepitopes were investigated by associating serum epitope enrichment scores with whole-genome sequencing results from paired solid tumor metastasis biopsies and germline blood samples. A protein-based immunome-wide association study (PIWAS) was performed to identify significantly enriched epitopes, and candidate serum antibodies enriched in select patients were validated by ELISA profiling. A distinct cohort of patients with melanoma was evaluated to validate the top cancer-specific epitopes.Results:SERA was performed on 1,229 serum samples obtained from 72 men with mCRPC and 1,157 healthy control patients. Twenty-nine of 6,636 somatic mutations (0.44%) were associated with an antibody response specific to the mutated peptide. PIWAS analyses identified motifs in 11 proteins, including NY-ESO-1 and HERVK-113, as immunogenic in mCRPC, and ELISA confirmed serum antibody enrichment in candidate patients. Confirmatory PIWAS, Identifying Motifs Using Next-generation sequencing Experiments (IMUNE), and ELISA analyses performed on serum samples from 106 patients with melanoma similarly revealed enriched cancer-specific antibody responses to NY-ESO-1.Conclusions:We present the first large-scale profiling of autoantibodies in advanced prostate cancer, utilizing a new antibody profiling approach to reveal novel cancer-specific antigens and epitopes. Our study recovers antigens of known importance and identifies novel tumor-specific epitopes of translational interest.

Published

2023

20. Supplementary Figure S3 from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Author

Joshi J. Alumkal, Zheng Xia, Joel A. Yates, Eric Campeau, Sanjay Lakhotia, Sarah Attwell, Emily M. Gesner, Arvind Rao, Armand Bankhead, Daniel E. Spratt, Eric J. Small, Felix Y. Feng, Wassim Abida, Rahul Aggarwal, Jonathan Z. Sexton, Samuel K. Handelman, Eva Corey, Peter S. Nelson, Ilsa M. Coleman, Jared M. Lucas, Colm Morrissey, Mark P. Labrecque, Himisha Beltran, Chao Zhang, Jacob A. Schwartzman, Joshua A. Urrutia, Eva S. Rodansky, Anbarasu Kumaraswamy, Xiangnan Guan, David Sampson, Daniel J. Coleman, Chelsea Jenkins, Katherine Welker Leng, William K. Storck, Duanchen Sun, and Dae-Hwan Kim

Abstract

Supplementary Figure S3 from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Published

2023

21. Data from RNA Splicing Factors SRRM3 and SRRM4 Distinguish Molecular Phenotypes of Castration-Resistant Neuroendocrine Prostate Cancer

Author

Colm Morrissey, Peter S. Nelson, Eva Corey, Joshi J. Alumkal, Hung-Ming Lam, Daniel W. Lin, Lawrence D. True, David S. Rickman, Michael C. Haffner, Brian Hanratty, Dapei Li, Holly M. Nguyen, John K. Lee, Nicholas J. Brady, Bryce Lakely, Ilsa M. Coleman, Lisha G. Brown, and Mark P. Labrecque

Abstract

Neuroendocrine (NE) differentiation in metastatic castration-resistant prostate cancer (mCRPC) is an increasingly common clinical feature arising from cellular plasticity. We recently characterized two mCRPC phenotypes with NE features: androgen receptor (AR)-positive NE-positive amphicrine prostate cancer (AMPC) and AR-negative small cell or neuroendocrine prostate cancer (SCNPC). Here, we interrogated the regulation of RE1-silencing transcription factor (REST), a transcriptional repressor of neuronal genes, and elucidated molecular programs driving AMPC and SCNPC biology. Analysis of prostate cancer cell lines, mCRPC specimens, and LuCaP patient-derived xenograft models detected alternative splicing of REST to REST4 and attenuated REST repressor activity in AMPC and SCNPC. The REST locus was also hypermethylated and REST expression was reduced in SCNPC. While serine/arginine repetitive matrix protein 4 (SRRM4) was previously implicated in alternative splicing of REST in mCRPC, we detected SRRM3 expression in REST4-positive, SRRM4-negative AMPC, and SCNPC. In CRPC cell lines, SRRM3 induced alternative splicing of REST to REST4 and exacerbated the expression of REST-repressed genes. Furthermore, SRRM3 and SRRM4 expression defined molecular subsets of AMPC and SCNPC across species and tumor types. Two AMPC phenotypes and three SCNPC phenotypes were characterized, denoted either by REST attenuation and ASCL1 activity or by progressive activation of neuronal transcription factor programs, respectively. These results nominate SRRM3 as the principal REST splicing factor expressed in early NE differentiation and provide a framework to molecularly classify diverse NE phenotypes in mCRPC.Significance:This study identifies SRRM3 as a key inducer of cellular plasticity in prostate cancer with neuroendocrine features and delineates distinct neuroendocrine phenotypes to inform therapeutic development and precision medicine applications.

Published

2023

22. Supplementary Tables S1-S12 from RNA Splicing Factors SRRM3 and SRRM4 Distinguish Molecular Phenotypes of Castration-Resistant Neuroendocrine Prostate Cancer

Author

Colm Morrissey, Peter S. Nelson, Eva Corey, Joshi J. Alumkal, Hung-Ming Lam, Daniel W. Lin, Lawrence D. True, David S. Rickman, Michael C. Haffner, Brian Hanratty, Dapei Li, Holly M. Nguyen, John K. Lee, Nicholas J. Brady, Bryce Lakely, Ilsa M. Coleman, Lisha G. Brown, and Mark P. Labrecque

Abstract

All supplementary tables. Tables S1-S12

Published

2023

23. Supplementary Figures S1-S9 from Autoantibody Landscape in Patients with Advanced Prostate Cancer

Author

Felix Y. Feng, John C. Shon, David Y. Oh, Antoni Ribas, Patrick S. Daugherty, Eric J. Small, Rahul Aggarwal, Alan Ashworth, Joshi J. Alumkal, Robert E. Reiter, Kim N. Chi, Primo Lara, Christopher P. Evans, Martin Gleave, Matthew Rettig, Tomasz M. Beer, Jonathan Chou, David A. Quigley, Martin Sjöström, Shuang G. Zhao, Meng Zhang, Ivan Perez Garcilazo, Ignacio Baselga Carretero, Adam Foye, Minlu Zhang, Raunak Shrestha, Agustin Vega-Crespo, Kathy Kamath, Rebecca Waitz, Winston A. Haynes, and William S. Chen

Abstract

Supplementary Figures S1-S9

Published

2023

24. Supplementary Dataset S1 from Copy Number Loss of 17q22 Is Associated with Enzalutamide Resistance and Poor Prognosis in Metastatic Castration-Resistant Prostate Cancer

Author

Joshi J. Alumkal, Zheng Xia, Eric J. Small, Felix Y. Feng, Joshua M. Stuart, Alana S. Weinstein, Jack Youngren, William S. Chen, Adam Foye, David A. Quigley, Rahul R. Aggarwal, Jiaoti Huang, George V. Thomas, Tomasz M. Beer, Martin Gleave, Primo Lara, Christopher P. Evans, Matthew Rettig, Robert Evan Reiter, Joshua A. Urrutia, Eric Lu, Duanchen Sun, and Xiangnan Guan

Abstract

Supplementary Dataset S1 shows the list of copy number gain genes.

Published

2023

25. Supplementary Data from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Author

Joshi J. Alumkal, Zheng Xia, Joel A. Yates, Eric Campeau, Sanjay Lakhotia, Sarah Attwell, Emily M. Gesner, Arvind Rao, Armand Bankhead, Daniel E. Spratt, Eric J. Small, Felix Y. Feng, Wassim Abida, Rahul Aggarwal, Jonathan Z. Sexton, Samuel K. Handelman, Eva Corey, Peter S. Nelson, Ilsa M. Coleman, Jared M. Lucas, Colm Morrissey, Mark P. Labrecque, Himisha Beltran, Chao Zhang, Jacob A. Schwartzman, Joshua A. Urrutia, Eva S. Rodansky, Anbarasu Kumaraswamy, Xiangnan Guan, David Sampson, Daniel J. Coleman, Chelsea Jenkins, Katherine Welker Leng, William K. Storck, Duanchen Sun, and Dae-Hwan Kim

Abstract

Supplementary Data from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Published

2023

26. Supplementary Materials and Methods from RNA Splicing Factors SRRM3 and SRRM4 Distinguish Molecular Phenotypes of Castration-Resistant Neuroendocrine Prostate Cancer

Author

Colm Morrissey, Peter S. Nelson, Eva Corey, Joshi J. Alumkal, Hung-Ming Lam, Daniel W. Lin, Lawrence D. True, David S. Rickman, Michael C. Haffner, Brian Hanratty, Dapei Li, Holly M. Nguyen, John K. Lee, Nicholas J. Brady, Bryce Lakely, Ilsa M. Coleman, Lisha G. Brown, and Mark P. Labrecque

Abstract

Supplementary Materials and Methods

Published

2023

27. Supplementary Table S2 S4 S6 S7 from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Author

Joshi J. Alumkal, Zheng Xia, Joel A. Yates, Eric Campeau, Sanjay Lakhotia, Sarah Attwell, Emily M. Gesner, Arvind Rao, Armand Bankhead, Daniel E. Spratt, Eric J. Small, Felix Y. Feng, Wassim Abida, Rahul Aggarwal, Jonathan Z. Sexton, Samuel K. Handelman, Eva Corey, Peter S. Nelson, Ilsa M. Coleman, Jared M. Lucas, Colm Morrissey, Mark P. Labrecque, Himisha Beltran, Chao Zhang, Jacob A. Schwartzman, Joshua A. Urrutia, Eva S. Rodansky, Anbarasu Kumaraswamy, Xiangnan Guan, David Sampson, Daniel J. Coleman, Chelsea Jenkins, Katherine Welker Leng, William K. Storck, Duanchen Sun, and Dae-Hwan Kim

Abstract

Supplementary Table S2 S4 S6 S7 from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Published

2023

28. Supplementary Figure 1 from Safety and Antitumor Activity of Apalutamide (ARN-509) in Metastatic Castration-Resistant Prostate Cancer with and without Prior Abiraterone Acetate and Prednisone

Author

Howard I. Scher, Margaret K. Yu, Carla J. de Boer, Edna Chow Maneval, Rajesh Bandekar, Ralph J. Hauke, Mansoor Saleh, Charles J. Ryan, Joshi J. Alumkal, Ronald F. Tutrone, Neal D. Shore, Emmanuel S. Antonarakis, and Dana E. Rathkopf

Abstract

Study design (A) and patient disposition (B); data cutoff December 31, 2014.

Published

2023

29. Supplementary Table 1 from A Phase Ib/IIa Study of the Pan-BET Inhibitor ZEN-3694 in Combination with Enzalutamide in Patients with Metastatic Castration-resistant Prostate Cancer

Author

Joshi J. Alumkal, Wassim Abida, Eric J. Small, Felix Y. Feng, Sanjay Lakhotia, Lisa Bauman, Margo Snyder, Karen Norek, Sarah Attwell, Eric Campeau, Elisabeth I. Heath, Allan J. Pantuck, David M. Nanus, Michael T. Schweizer, and Rahul R. Aggarwal

Abstract

Supplementary Table 1

Published

2023

30. Data from A Phase Ib/IIa Study of the Pan-BET Inhibitor ZEN-3694 in Combination with Enzalutamide in Patients with Metastatic Castration-resistant Prostate Cancer

Author

Joshi J. Alumkal, Wassim Abida, Eric J. Small, Felix Y. Feng, Sanjay Lakhotia, Lisa Bauman, Margo Snyder, Karen Norek, Sarah Attwell, Eric Campeau, Elisabeth I. Heath, Allan J. Pantuck, David M. Nanus, Michael T. Schweizer, and Rahul R. Aggarwal

Abstract

Purpose:ZEN-3694 is a bromodomain extraterminal inhibitor (BETi) with activity in androgen-signaling inhibitor (ASI)-resistant models. The safety and efficacy of ZEN-3694 plus enzalutamide was evaluated in a phase Ib/IIa study in metastatic castration-resistant prostate cancer (mCRPC).Patients and Methods:Patients had progressive mCRPC with prior resistance to abiraterone and/or enzalutamide. 3+3 dose escalation was followed by dose expansion in parallel cohorts (ZEN-3694 at 48 and 96 mg orally once daily, respectively).Results:Seventy-five patients were enrolled (N = 26 and 14 in dose expansion at low- and high-dose ZEN-3694, respectively). Thirty (40.0%) patients were resistant to abiraterone, 34 (45.3%) to enzalutamide, and 11 (14.7%) to both. ZEN-3694 dosing ranged from 36 to 144 mg daily without reaching an MTD. Fourteen patients (18.7%) experienced grade ≥3 toxicities, including three patients with grade 3 thrombocytopenia (4%). An exposure-dependent decrease in whole-blood RNA expression of BETi targets was observed (up to fourfold mean difference at 4 hours post–ZEN-3694 dose; P ≤ 0.0001). The median radiographic progression-free survival (rPFS) was 9.0 months [95% confidence interval (CI), 4.6–12.9] and composite median radiographic or clinical progression-free survival (PFS) was 5.5 months (95% CI, 4.0–7.8). Median duration of treatment was 3.5 months (range, 0–34.7+). Lower androgen receptor (AR) transcriptional activity in baseline tumor biopsies was associated with longer rPFS (median rPFS 10.4 vs. 4.3 months).Conclusions:ZEN-3694 plus enzalutamide demonstrated acceptable tolerability and potential efficacy in patients with ASI-resistant mCRPC. Further prospective study is warranted including in mCRPC harboring low AR transcriptional activity.

Published

2023

31. Supplementary Data from Epigenetic Therapy with Panobinostat Combined with Bicalutamide Rechallenge in Castration-Resistant Prostate Cancer

Author

Tomasz M. Beer, Robert DiPaola, Dirk Moore, Xiaomei Liu, Alejandro Gomez-Pinillos, Ethan S. Barnett, James Babb, Mary-Ellen Taplin, Mark N. Stein, Joshi J. Alumkal, and Anna C. Ferrari

Abstract

Supplementary methods and Figure S1

Published

2023

32. Data from Copy Number Loss of 17q22 Is Associated with Enzalutamide Resistance and Poor Prognosis in Metastatic Castration-Resistant Prostate Cancer

Author

Joshi J. Alumkal, Zheng Xia, Eric J. Small, Felix Y. Feng, Joshua M. Stuart, Alana S. Weinstein, Jack Youngren, William S. Chen, Adam Foye, David A. Quigley, Rahul R. Aggarwal, Jiaoti Huang, George V. Thomas, Tomasz M. Beer, Martin Gleave, Primo Lara, Christopher P. Evans, Matthew Rettig, Robert Evan Reiter, Joshua A. Urrutia, Eric Lu, Duanchen Sun, and Xiangnan Guan

Abstract

Purpose:The purpose of this study was to measure genomic changes that emerge with enzalutamide treatment using analyses of whole-genome sequencing and RNA sequencing.Experimental Design:One hundred and one tumors from men with metastatic castration-resistant prostate cancer (mCRPC) who had not been treated with enzalutamide (n = 64) or who had enzalutamide-resistant mCRPC (n = 37) underwent whole genome sequencing. Ninety-nine of these tumors also underwent RNA sequencing. We analyzed the genomes and transcriptomes of these mCRPC tumors.Results:Copy number loss was more common than gain in enzalutamide-resistant tumors. Specially, we identified 124 protein-coding genes that were more commonly lost in enzalutamide-resistant samples. These 124 genes included eight putative tumor suppressors located at nine distinct genomic regions. We demonstrated that focal deletion of the 17q22 locus that includes RNF43 and SRSF1 was not present in any patient with enzalutamide-naïve mCRPC but was present in 16% (6/37) of patients with enzalutamide-resistant mCRPC. 17q22 loss was associated with lower RNF43 and SRSF1 expression and poor overall survival from time of biopsy [median overall survival of 19.3 months in 17q22 intact vs. 8.9 months in 17q22 loss, HR, 3.44 95% confidence interval (CI), 1.338–8.867, log-rank P = 0.006]. Finally, 17q22 loss was linked with activation of several targetable factors, including CDK1/2, Akt, and PLK1, demonstrating the potential therapeutic relevance of 17q22 loss in mCRPC.Conclusions:Copy number loss is common in enzalutamide-resistant tumors. Focal deletion of chromosome 17q22 defines a previously unappreciated molecular subset of enzalutamide-resistant mCRPC associated with poor clinical outcome.

Published

2023

33. Data from Epigenetic Therapy with Panobinostat Combined with Bicalutamide Rechallenge in Castration-Resistant Prostate Cancer

Author

Tomasz M. Beer, Robert DiPaola, Dirk Moore, Xiaomei Liu, Alejandro Gomez-Pinillos, Ethan S. Barnett, James Babb, Mary-Ellen Taplin, Mark N. Stein, Joshi J. Alumkal, and Anna C. Ferrari

Abstract

Purpose:This study assesses the action of panobinostat, a histone deacetylase inhibitor (HDACI), in restoring sensitivity to bicalutamide in a castration-resistant prostate cancer (CRPC) model and the efficacy and safety of the panobinostat/bicalutamide combination in CRPC patients resistant to second-line antiandrogen therapy (2ndLAARx).Patients and Methods:The CWR22PC xenograft and isogenic cell line were tested for drug interactions on tumor cell growth and on the androgen receptor (AR), AR-splice variant7, and AR targets. A phase I trial had a 3 × 3 panobinostat dose-escalation design. The phase II study randomized 55 patients to panobinostat 40 mg (A arm) or 20 mg (B arm) triweekly ×2 weeks with bicalutamide 50 mg/day in 3-week cycles. The primary endpoint was to determine the percentage of radiographic progression-free (rPF) patients at 36 weeks versus historic high-dose bicalutamide.Results:In the model, panobinostat/bicalutamide demonstrated synergistic antitumor effect while reducing AR activity. The dose-limiting toxicity was not reached. The probabilities of remaining rPF were 47.5% in the A arm and 38.5% in the B arm, exceeding the protocol-specified threshold of 35%. The A arm but not the B arm exceeded expectations for times (medians) to rP (33.9 and 10 weeks), and from PSA progression to rP (24 and 5.9 weeks). A arm/B arm events included: adverse events (AE), 62%/19%; treatment stopped for AEs, 27.5%/11.5%; dose reduction required, 41%/4%. The principal A-arm grade ≥ 3 AEs were thrombocytopenia (31%) and fatigue (14%).Conclusions:The 40 mg panobinostat/bicalutamide regimen increased rPF survival in CRPC patients resistant to 2ndLAARx. Panobinostat toxicity was tolerable with dose reductions. Epigenetic HDACI therapy reduces AR-mediated resistance to bicalutamide in CRPC models with clinical benefit in patients. The combination merits validation using a second-generation antiandrogen.

Published

2023

34. Data from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Author

Joshi J. Alumkal, Zheng Xia, Joel A. Yates, Eric Campeau, Sanjay Lakhotia, Sarah Attwell, Emily M. Gesner, Arvind Rao, Armand Bankhead, Daniel E. Spratt, Eric J. Small, Felix Y. Feng, Wassim Abida, Rahul Aggarwal, Jonathan Z. Sexton, Samuel K. Handelman, Eva Corey, Peter S. Nelson, Ilsa M. Coleman, Jared M. Lucas, Colm Morrissey, Mark P. Labrecque, Himisha Beltran, Chao Zhang, Jacob A. Schwartzman, Joshua A. Urrutia, Eva S. Rodansky, Anbarasu Kumaraswamy, Xiangnan Guan, David Sampson, Daniel J. Coleman, Chelsea Jenkins, Katherine Welker Leng, William K. Storck, Duanchen Sun, and Dae-Hwan Kim

Abstract

Purpose:Lineage plasticity in prostate cancer—most commonly exemplified by loss of androgen receptor (AR) signaling and a switch from a luminal to alternate differentiation program—is now recognized as a treatment resistance mechanism. Lineage plasticity is a spectrum, but neuroendocrine prostate cancer (NEPC) is the most virulent example. Currently, there are limited treatments for NEPC. Moreover, the incidence of treatment-emergent NEPC (t-NEPC) is increasing in the era of novel AR inhibitors. In contradistinction to de novo NEPC, t-NEPC tumors often express the AR, but AR's functional role in t-NEPC is unknown. Furthermore, targetable factors that promote t-NEPC lineage plasticity are also unclear.Experimental Design:Using an integrative systems biology approach, we investigated enzalutamide-resistant t-NEPC cell lines and their parental, enzalutamide-sensitive adenocarcinoma cell lines. The AR is still expressed in these t-NEPC cells, enabling us to determine the role of the AR and other key factors in regulating t-NEPC lineage plasticity.Results:AR inhibition accentuates lineage plasticity in t-NEPC cells—an effect not observed in parental, enzalutamide-sensitive adenocarcinoma cells. Induction of an AR-repressed, lineage plasticity program is dependent on activation of the transcription factor E2F1 in concert with the BET bromodomain chromatin reader BRD4. BET inhibition (BETi) blocks this E2F1/BRD4-regulated program and decreases growth of t-NEPC tumor models and a subset of t-NEPC patient tumors with high activity of this program in a BETi clinical trial.Conclusions:E2F1 and BRD4 are critical for activating an AR-repressed, t-NEPC lineage plasticity program. BETi is a promising approach to block this program.

Published

2023

35. Supplementary Figure 1 from A Phase Ib/IIa Study of the Pan-BET Inhibitor ZEN-3694 in Combination with Enzalutamide in Patients with Metastatic Castration-resistant Prostate Cancer

Author

Joshi J. Alumkal, Wassim Abida, Eric J. Small, Felix Y. Feng, Sanjay Lakhotia, Lisa Bauman, Margo Snyder, Karen Norek, Sarah Attwell, Eric Campeau, Elisabeth I. Heath, Allan J. Pantuck, David M. Nanus, Michael T. Schweizer, and Rahul R. Aggarwal

Abstract

Supplementary Figure 1

Published

2023

36. Data Supplement from Phase II Study of Single-Agent Orteronel (TAK-700) in Patients with Nonmetastatic Castration-Resistant Prostate Cancer and Rising Prostate-Specific Antigen

Author

Daniel J. George, H. Mark Lin, Shih-Yuan Lee, Susan Moran, Justine Y. Bruce, Charles J. Ryan, Joshi J. Alumkal, Hans J. Hammers, M. Dror Michaelson, Paul G. Corn, and Maha Hussain

Abstract

Supplementary Table S1- Number of patients with 1-4 and {greater than or equal to}5 CTCs per 7.5mL of whole blood at baseline, and at 3, 6 and 12 months. Supplementary Table S2- Biochemical markers of bone turnover and bone mineral density (BMD).

Published

2023

37. Data from Safety and Antitumor Activity of Apalutamide (ARN-509) in Metastatic Castration-Resistant Prostate Cancer with and without Prior Abiraterone Acetate and Prednisone

Author

Howard I. Scher, Margaret K. Yu, Carla J. de Boer, Edna Chow Maneval, Rajesh Bandekar, Ralph J. Hauke, Mansoor Saleh, Charles J. Ryan, Joshi J. Alumkal, Ronald F. Tutrone, Neal D. Shore, Emmanuel S. Antonarakis, and Dana E. Rathkopf

Abstract

Purpose: To evaluate the efficacy of apalutamide before or after treatment with abiraterone acetate and prednisone (AAP) in patients with progressive metastatic castration-resistant prostate cancer (mCRPC).Experimental Design: Two cohorts were studied: AAP-naïve and post-AAP patients who had received ≥6 months of AAP. Patients had progressive mCRPC per rising prostate-specific antigen (PSA) and/or imaging, without prior chemotherapy exposure. All received apalutamide 240 mg/day. Primary endpoint was ≥50% decline in 12-week PSA according to Prostate Cancer Working Group 2 criteria. Secondary endpoints included time to PSA progression and time on treatment.Results: Forty-six patients enrolled in the AAP-naïve (n = 25) and post-AAP (n = 21) cohorts. The 12-week PSA response rate was 88% (22/25) and 22% (4/18), median time to PSA progression was 18.2 months [95% confidence interval (CI), 8.3 months–not reached) and 3.7 months (95% CI, 2.8–5.6 months), and median time on treatment 21 months (range, 2.6–37.5) and 4.9 months (range, 1.3–23.2), for the AAP-naïve and post-AAP cohorts, respectively. Eighty percent (95% CI, 59–93) and 64% (95% CI, 43–82) of AAP-naïve and 43% (95% CI, 22–66) and 10% (95% CI, 1–30) of post-AAP patients remained on treatment for 6+ and 12+ months, respectively. Common treatment-emergent adverse events in both cohorts were grade 1 or 2 fatigue, diarrhea, nausea, and abdominal pain.Conclusions: Apalutamide was safe, well tolerated, and demonstrated clinical activity in mCRPC, with 80% of AAP-naïve and 43% of post-AAP patients, remaining on treatment for 6 months or longer. Clin Cancer Res; 23(14); 3544–51. ©2017 AACR.

Published

2023

38. Supplementary Table S8-S12 from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Author

Joshi J. Alumkal, Zheng Xia, Joel A. Yates, Eric Campeau, Sanjay Lakhotia, Sarah Attwell, Emily M. Gesner, Arvind Rao, Armand Bankhead, Daniel E. Spratt, Eric J. Small, Felix Y. Feng, Wassim Abida, Rahul Aggarwal, Jonathan Z. Sexton, Samuel K. Handelman, Eva Corey, Peter S. Nelson, Ilsa M. Coleman, Jared M. Lucas, Colm Morrissey, Mark P. Labrecque, Himisha Beltran, Chao Zhang, Jacob A. Schwartzman, Joshua A. Urrutia, Eva S. Rodansky, Anbarasu Kumaraswamy, Xiangnan Guan, David Sampson, Daniel J. Coleman, Chelsea Jenkins, Katherine Welker Leng, William K. Storck, Duanchen Sun, and Dae-Hwan Kim

Abstract

Supplementary Table S8-S12 from BET Bromodomain Inhibition Blocks an AR-Repressed, E2F1-Activated Treatment-Emergent Neuroendocrine Prostate Cancer Lineage Plasticity Program

Published

2023

39. Supplementary Figures S1-S13 from RNA Splicing Factors SRRM3 and SRRM4 Distinguish Molecular Phenotypes of Castration-Resistant Neuroendocrine Prostate Cancer

Author

Colm Morrissey, Peter S. Nelson, Eva Corey, Joshi J. Alumkal, Hung-Ming Lam, Daniel W. Lin, Lawrence D. True, David S. Rickman, Michael C. Haffner, Brian Hanratty, Dapei Li, Holly M. Nguyen, John K. Lee, Nicholas J. Brady, Bryce Lakely, Ilsa M. Coleman, Lisha G. Brown, and Mark P. Labrecque

Abstract

All Supplementary Figures. Figures S1-S13

Published

2023

40. Supplementary Figure Legend from Copy Number Loss of 17q22 Is Associated with Enzalutamide Resistance and Poor Prognosis in Metastatic Castration-Resistant Prostate Cancer

Author

Joshi J. Alumkal, Zheng Xia, Eric J. Small, Felix Y. Feng, Joshua M. Stuart, Alana S. Weinstein, Jack Youngren, William S. Chen, Adam Foye, David A. Quigley, Rahul R. Aggarwal, Jiaoti Huang, George V. Thomas, Tomasz M. Beer, Martin Gleave, Primo Lara, Christopher P. Evans, Matthew Rettig, Robert Evan Reiter, Joshua A. Urrutia, Eric Lu, Duanchen Sun, and Xiangnan Guan

Abstract

Supplementary Figure Legend contains the description of supplementary Figure S1-S4 and supplementary Datasets S1-S2.

Published

2023

41. Supplementary Tables S1-S4 from Autoantibody Landscape in Patients with Advanced Prostate Cancer

Author

Felix Y. Feng, John C. Shon, David Y. Oh, Antoni Ribas, Patrick S. Daugherty, Eric J. Small, Rahul Aggarwal, Alan Ashworth, Joshi J. Alumkal, Robert E. Reiter, Kim N. Chi, Primo Lara, Christopher P. Evans, Martin Gleave, Matthew Rettig, Tomasz M. Beer, Jonathan Chou, David A. Quigley, Martin Sjöström, Shuang G. Zhao, Meng Zhang, Ivan Perez Garcilazo, Ignacio Baselga Carretero, Adam Foye, Minlu Zhang, Raunak Shrestha, Agustin Vega-Crespo, Kathy Kamath, Rebecca Waitz, Winston A. Haynes, and William S. Chen

Abstract

Supplementary Tables S1-S4

Published

2023

42. Supplementary Table S1 from Copy Number Loss of 17q22 Is Associated with Enzalutamide Resistance and Poor Prognosis in Metastatic Castration-Resistant Prostate Cancer

Author

Joshi J. Alumkal, Zheng Xia, Eric J. Small, Felix Y. Feng, Joshua M. Stuart, Alana S. Weinstein, Jack Youngren, William S. Chen, Adam Foye, David A. Quigley, Rahul R. Aggarwal, Jiaoti Huang, George V. Thomas, Tomasz M. Beer, Martin Gleave, Primo Lara, Christopher P. Evans, Matthew Rettig, Robert Evan Reiter, Joshua A. Urrutia, Eric Lu, Duanchen Sun, and Xiangnan Guan

Abstract

Supplementary Table S1 shows the univariable survival analysis.

Published

2023

43. Supplementary Figure 2 from A Phase Ib/IIa Study of the Pan-BET Inhibitor ZEN-3694 in Combination with Enzalutamide in Patients with Metastatic Castration-resistant Prostate Cancer

Author

Joshi J. Alumkal, Wassim Abida, Eric J. Small, Felix Y. Feng, Sanjay Lakhotia, Lisa Bauman, Margo Snyder, Karen Norek, Sarah Attwell, Eric Campeau, Elisabeth I. Heath, Allan J. Pantuck, David M. Nanus, Michael T. Schweizer, and Rahul R. Aggarwal

Abstract

Supplementary Figure 2

Published

2023

44. The 5-Hydroxymethylcytosine Landscape of Prostate Cancer

Author

Martin Sjöström, Shuang G. Zhao, Samuel Levy, Meng Zhang, Yuhong Ning, Raunak Shrestha, Arian Lundberg, Cameron Herberts, Adam Foye, Rahul Aggarwal, Junjie T. Hua, Haolong Li, Anna Bergamaschi, Corinne Maurice-Dror, Ashutosh Maheshwari, Sujun Chen, Sarah W.S. Ng, Wenbin Ye, Jessica Petricca, Michael Fraser, Lisa Chesner, Marc D. Perry, Thaidy Moreno-Rodriguez, William S. Chen, Joshi J. Alumkal, Jonathan Chou, Alicia K. Morgans, Tomasz M. Beer, George V. Thomas, Martin Gleave, Paul Lloyd, Tierney Phillips, Erin McCarthy, Michael C. Haffner, Amina Zoubeidi, Matti Annala, Robert E. Reiter, Matthew B. Rettig, Owen N. Witte, Lawrence Fong, Rohit Bose, Franklin W. Huang, Jianhua Luo, Anders Bjartell, Joshua M. Lang, Nupam P. Mahajan, Primo N. Lara, Christopher P. Evans, Phuoc T. Tran, Edwin M. Posadas, Chuan He, Xiao-Long Cui, Jiaoti Huang, Wilbert Zwart, Luke A. Gilbert, Christopher A. Maher, Paul C. Boutros, Kim N. Chi, Alan Ashworth, Eric J. Small, Housheng H. He, Alexander W. Wyatt, David A. Quigley, Felix Y. Feng, Tampere University, and BioMediTech

Subjects

Male, Cancer Research, Oncology, Biopsy, 5-Methylcytosine, Prostate, Humans, Prostatic Neoplasms, 3111 Biomedicine

Abstract

Analysis of DNA methylation is a valuable tool to understand disease progression and is increasingly being used to create diagnostic and prognostic clinical biomarkers. While conversion of cytosine to 5-methylcytosine (5mC) commonly results in transcriptional repression, further conversion to 5-hydroxymethylcytosine (5hmC) is associated with transcriptional activation. Here we perform the first study integrating whole-genome 5hmC with DNA, 5mC, and transcriptome sequencing in clinical samples of benign, localized, and advanced prostate cancer. 5hmC is shown to mark activation of cancer drivers and downstream targets. Furthermore, 5hmC sequencing revealed profoundly altered cell states throughout the disease course, characterized by increased proliferation, oncogenic signaling, dedifferentiation, and lineage plasticity to neuroendocrine and gastrointestinal lineages. Finally, 5hmC sequencing of cell-free DNA from patients with metastatic disease proved useful as a prognostic biomarker able to identify an aggressive subtype of prostate cancer using the genes TOP2A and EZH2, previously only detectable by transcriptomic analysis of solid tumor biopsies. Overall, these findings reveal that 5hmC marks epigenomic activation in prostate cancer and identify hallmarks of prostate cancer progression with potential as biomarkers of aggressive disease. Significance: In prostate cancer, 5-hydroxymethylcytosine delineates oncogene activation and stage-specific cell states and can be analyzed in liquid biopsies to detect cancer phenotypes. See related article by Wu and Attard, p. 3880

Published

2022

45. The heterogeneity of prostate cancers lacking AR activity will require diverse treatment approaches

Author

Colm Morrissey, Joshi J. Alumkal, Peter S. Nelson, Mark P. Labrecque, and Ilsa Coleman

Subjects

Male, Cancer Research, Endocrinology, Diabetes and Metabolism, Cell Cycle Proteins, urologic and male genital diseases, Article, Androgen deprivation therapy, Prostate cancer, Endocrinology, SOX2, Cell Line, Tumor, Humans, Medicine, Epigenetics, business.industry, EZH2, Nuclear Proteins, Androgen Antagonists, medicine.disease, Gene Expression Regulation, Neoplastic, Androgen receptor, Prostatic Neoplasms, Castration-Resistant, Oncology, Receptors, Androgen, DNA methylation, Cancer research, NBAF complex, business, Signal Transduction, Transcription Factors

Abstract

The use of androgen deprivation therapy and second-line anti-androgens in prostate cancer has led to the emergence of tumors employing multiple androgen receptor (AR)-dependent and AR-independent mechanisms to resist AR-targeted therapies in castration-resistant prostate cancer (CRPC). While the AR signaling axis remains the cornerstone for therapeutic development in CRPC, a clearer understanding of the heterogeneous biology of CRPC tumors is needed for innovative treatment strategies. In this review, we discuss the characteristics of CRPC tumors that lack AR activity and the temporal and spatial considerations for the conversion of an AR-dependent to an AR-independent tumor type. We describe the more prevalent treatment-emergent phenotypes arising in the CRPC disease continuum, including amphicrine, AR-low, double-negative, neuroendocrine and small cell phenotypes. We discuss the association between the loss of AR activity and tumor plasticity with a focus on the roles of transcription factors like SOX2, DNA methylation, alternative splicing, and the activity of epigenetic modifiers like EZH2, BRD4, LSD1, and the nBAF complex in conversion to a neuroendocrine or small cell phenotype in CRPC. We hypothesize that only a subset of CRPC tumors have the propensity for tumor plasticity and conversion to the neuroendocrine phenotype and outline how we might target these plastic and emergent phenotypes in CRPC. In conclusion, we assess the current and future avenues for treatment and determine that the heterogeneity of CRPCs lacking AR activity will require diverse treatment approaches.

Published

2021

46. RNA Splicing Factors SRRM3 and SRRM4 Distinguish Molecular Phenotypes of Castration-Resistant Neuroendocrine Prostate Cancer

Author

Dapei Li, John K. Lee, Brian Hanratty, Nicholas J. Brady, Daniel W. Lin, Colm Morrissey, Lawrence D. True, Peter S. Nelson, Ilsa Coleman, Bryce Lakely, Eva Corey, Hung-Ming Lam, Joshi J. Alumkal, Michael C. Haffner, Mark P. Labrecque, Lisha G. Brown, David S. Rickman, and Holly M. Nguyen

Subjects

Male, RNA Splicing Factors, Cancer Research, Repressor, Nerve Tissue Proteins, Biology, Article, Ectopic Gene Expression, Prostate cancer, Splicing factor, Cell Line, Tumor, Biomarkers, Tumor, medicine, Humans, Transcription factor, Alternative splicing, Proteins, medicine.disease, Immunohistochemistry, Phenotype, Carcinoma, Neuroendocrine, Gene Expression Regulation, Neoplastic, Repressor Proteins, Androgen receptor, Alternative Splicing, Prostatic Neoplasms, Castration-Resistant, Oncology, Cancer research

Abstract

Neuroendocrine (NE) differentiation in metastatic castration-resistant prostate cancer (mCRPC) is an increasingly common clinical feature arising from cellular plasticity. We recently characterized two mCRPC phenotypes with NE features: androgen receptor (AR)-positive NE-positive amphicrine prostate cancer (AMPC) and AR-negative small cell or neuroendocrine prostate cancer (SCNPC). Here, we interrogated the regulation of RE1-silencing transcription factor (REST), a transcriptional repressor of neuronal genes, and elucidated molecular programs driving AMPC and SCNPC biology. Analysis of prostate cancer cell lines, mCRPC specimens, and LuCaP patient-derived xenograft models detected alternative splicing of REST to REST4 and attenuated REST repressor activity in AMPC and SCNPC. The REST locus was also hypermethylated and REST expression was reduced in SCNPC. While serine/arginine repetitive matrix protein 4 (SRRM4) was previously implicated in alternative splicing of REST in mCRPC, we detected SRRM3 expression in REST4-positive, SRRM4-negative AMPC, and SCNPC. In CRPC cell lines, SRRM3 induced alternative splicing of REST to REST4 and exacerbated the expression of REST-repressed genes. Furthermore, SRRM3 and SRRM4 expression defined molecular subsets of AMPC and SCNPC across species and tumor types. Two AMPC phenotypes and three SCNPC phenotypes were characterized, denoted either by REST attenuation and ASCL1 activity or by progressive activation of neuronal transcription factor programs, respectively. These results nominate SRRM3 as the principal REST splicing factor expressed in early NE differentiation and provide a framework to molecularly classify diverse NE phenotypes in mCRPC. Significance: This study identifies SRRM3 as a key inducer of cellular plasticity in prostate cancer with neuroendocrine features and delineates distinct neuroendocrine phenotypes to inform therapeutic development and precision medicine applications.

Published

2021

47. Recent Advances in Epigenetic Biomarkers and Epigenetic Targeting in Prostate Cancer

Author

Anbarasu Kumaraswamy, Joel A. Yates, Felix Y. Feng, Thomas C. Westbrook, Joshi J. Alumkal, Todd M. Morgan, Katherine R. Welker Leng, Christopher P. Evans, and Shuang G. Zhao

Subjects

Male, Urology, 030232 urology & nephrology, Context (language use), Bioinformatics, Article, Epigenesis, Genetic, 03 medical and health sciences, Prostate cancer, 0302 clinical medicine, Humans, Medicine, Epigenetics, business.industry, Prostatic Neoplasms, DNA Methylation, medicine.disease, Clinical trial, Systematic review, Pharmaceutical Preparations, 030220 oncology & carcinogenesis, Histone methyltransferase, DNA methylation, Histone deacetylase, business, Biomarkers

Abstract

Context In addition to genetic alterations, epigenetic alterations play a crucial role during prostate cancer progression. A better understanding of the epigenetic factors that promote prostate cancer progression may lead to the design of rational therapeutic strategies to target prostate cancer more effectively. Objective To systematically review recent literature on the role of epigenetic factors in prostate cancer and highlight key preclinical and translational data with epigenetic therapies. Evidence acquisition We performed a systemic literature search in PubMed. At the request of the editors, we limited our search to articles published between January 2015 and August 2020 in accordance with the Preferred Reporting Items for Systematic Reviews and Meta-analyses (PRISMA) guidelines. Clinical trials targeting epigenetic factors were retrieved from clinicaltrials.gov. Evidence synthesis We retrieved 1451 articles, and 62 were finally selected for review. Twelve additional foundational studies outside this time frame were also included. Findings from both preclinical and clinical studies were reviewed and summarized. We also discuss 12 ongoing clinical studies with epigenetic targeted therapies. Conclusions Epigenetic mechanisms impact prostate cancer progression. Understanding the role of specific epigenetic factors is critical to determine how we may improve prostate cancer treatment and modulate resistance to standard therapies. Recent preclinical studies and ongoing or completed clinical studies with epigenetic therapies provide a useful roadmap for how to best deploy epigenetic therapies clinically to target prostate cancer. Patient summary Epigenetics is a process by which gene expression is regulated without changes in the DNA sequence itself. Oftentimes, epigenetic changes influence cellular behavior and contribute to cancer development or progression. Understanding how epigenetic changes occur in prostate cancer is the first step toward therapeutic targeting in patients. Importantly, laboratory-based studies and recently completed and ongoing clinical trials suggest that drugs targeting epigenetic factors are promising. More work is necessary to determine whether this class of drugs will add to our existing treatment arsenal in prostate cancer.

Published

2021

48. Intermediate clinical endpoints for surrogacy in localised prostate cancer: an aggregate meta-analysis

Author

E. Jaworski, Zachery R. Reichert, Gavin P. Jones, David G. Wallington, Todd M. Morgan, David Elliott, Brandon A. Mahal, Joshi J. Alumkal, Felix Y. Feng, S. Birer, Matthew J. Schipper, Edward M. Schaeffer, William C. Jackson, Amar U. Kishan, Rohit Mehra, Paul L. Nguyen, Matthew R. McFarlane, Karim Fizazi, L.A. Gharzai, Daniel E. Spratt, Howard M. Sandler, Susan Halabi, Robert T. Dess, Ralph Jiang, and Neil K. Jairath

Subjects

Male, Oncology, medicine.medical_specialty, 03 medical and health sciences, Prostate cancer, 0302 clinical medicine, Prostate, Internal medicine, medicine, Clinical endpoint, Humans, 030212 general & internal medicine, Survival rate, Aged, business.industry, Surrogate endpoint, Hazard ratio, Prostatic Neoplasms, Cancer, Prognosis, medicine.disease, Combined Modality Therapy, Survival Rate, medicine.anatomical_structure, Lymphatic Metastasis, 030220 oncology & carcinogenesis, Meta-analysis, Neoplasm Recurrence, Local, business, Biomarkers, Follow-Up Studies

Abstract

Summary Background The international Intermediate Clinical Endpoints in Cancer of the Prostate working group has established metastasis-free survival as a surrogate for overall survival in localised prostate cancer based on the findings of 19 predominantly radiotherapy-based trials. We sought to comprehensively assess aggregate trial-level performance of commonly reported intermediate clinical endpoints across all randomised trials in localised prostate cancer. Methods For this meta-analysis, we searched PubMed for all trials in localised or biochemically recurrent prostate cancer published between Jan 1, 1970, and Jan 15, 2020. Eligible trials had to be randomised, therapeutic, reporting overall survival and at least one intermediate clinical endpoint, and with a sample size of at least 70 participants. Trials of metastatic disease were excluded. Intermediate clinical endpoints included biochemical failure, local failure, distant metastases, biochemical failure-free survival, progression-free survival, and metastasis-free survival. Candidacy for surrogacy was assessed using the second condition of the meta-analytical approach (ie, correlation of the treatment effect of the intermediate clinical endpoint and overall survival), using R2 weighted by the inverse variance of the log intermediate clinical endpoint hazard ratio. The intermediate clinical endpoint was deemed to be a surrogate for overall survival if R2 was 0·7 or greater. Findings 75 trials (53 631 patients) were included in our analysis. Median follow-up was 9·1 years (IQR 5·7–10·6). Biochemical failure (R2 0·38 [95% CI 0·11–0·64]), biochemical failure-free survival (R2 0·12 [0·0030–0·33]), biochemical failure and clinical failure (R2 0·28 [0·0045–0·65]), and local failure (R2 0·085 [0·00–0·37]) correlated poorly with overall survival. Progression-free survival (R2 0·46 [95% CI 0·22–0·67]) showed moderate correlation with overall survival, and metastasis-free survival (R2 0·78 [0·59–0·89]) correlated strongly. Interpretation Intermediate clinical endpoints based on biochemical and local failure did not meet the second condition of the meta-analytical approach and are not surrogate endpoints for overall survival in localised prostate cancer. Our findings validate metastasis-free survival as the only identified surrogate endpoint for overall survival to date. Funding Prostate Cancer Foundation and National Institutes of Health.

Published

2021

49. Accelerating precision medicine in metastatic prostate cancer

Author

Joaquin Mateo, Arul M. Chinnaiyan, William Oh, Maha Hussain, Nikolaus Schultz, Howard R. Soule, Eric J. Small, Rana R. McKay, Rahul Aggarwal, Wassim Abida, Fatima Karzai, David B. Solit, Eliezer M. Van Allen, Felix Y. Feng, Jake Vinson, Bruce Montgomery, Vaibhav G. Patel, Matthew R. Smith, David J. VanderWeele, Julie N. Graff, Himisha Beltran, William L. Dahut, Matthew Rettig, Dana E. Rathkopf, Andrea K. Miyahira, Ajjai Alva, Jonathan W. Simons, Cora N. Sternberg, Xin Gao, and Joshi J. Alumkal

Subjects

Urologic Diseases, Male, Aging, Cancer Research, medicine.medical_specialty, Disease, Medical Oncology, Article, 03 medical and health sciences, Prostate cancer, 0302 clinical medicine, Clinical Research, Genetics, Humans, Medicine, In patient, Precision Medicine, Intensive care medicine, Early Detection of Cancer, Cancer, business.industry, Prostate Cancer, Genomic sequencing, Human Genome, Prostatic Neoplasms, Disease classification, Health Services, Prostate-Specific Antigen, Precision medicine, medicine.disease, Good Health and Well Being, Oncology, Drug development, Precision oncology, 030220 oncology & carcinogenesis, business, Biotechnology

Abstract

Despite advances in the screening and treatment of prostate cancer, the therapy options available, particularly for later stages of the disease, remain limited, and the treatment-resistant setting represents a serious unmet medical need. Moreover, disease heterogeneity and disparities in patient access to medical advances result in considerable variability in outcomes across patients. Disease classification based on genomic sequencing is a promising approach for identifying patients whose tumors exhibit actionable targets and for making more informed treatment decisions. Here we discuss how precision oncology can be accelerated to inform broader genomically driven clinical decisions for men with advanced prostate cancer, to inform drug development and, ultimately, to contribute to new treatment paradigms. Beltran and colleagues discuss the challenges in treating metastatic prostate cancer and strategies to accelerate precision oncology and improve therapy and clinical decisions in this setting.

Published

2020

50. Double-Negative Prostate Cancer Masquerading as a Squamous Cancer of Unknown Primary: A Clinicopathologic and Genomic Sequencing-Based Case Study

Author

Chandan Kumar-Sinha, Yi-Mi Wu, Dan R. Robinson, Joshi J. Alumkal, Frank C. Cackowski, Arul M. Chinnaiyan, and Rohit Mehra

Subjects

Oncology, Cancer Research, medicine.medical_specialty, business.industry, Genomic sequencing, Double negative, MEDLINE, Case Reports, medicine.disease, Prostate cancer, Based case study, Internal medicine, medicine, Unknown primary, Squamous cancer, business

Published

2020