Oncogenic genomic alterations, clinical phenotypes, and outcomes in metastatic castration-sensitive prostate cancer

Konrad H Stopsack; Subhiksha Nandakumar; Andreas G Wibmer; Samuel Haywood; Emily S Weg; Ethan S Barnett; Chloe J Kim; Emily A Carbone; Samantha E Vasselman; Bastien Nguyen; Melanie A Hullings; Howard I Scher; Michael J Morris; David B Solit; Nikolaus Schultz; Philip W Kantoff; Wassim Abida

doi:10.1158/1078-0432.CCR-20-0168

. Author manuscript; available in PMC: 2021 Jan 1.

Published in final edited form as: Clin Cancer Res. 2020 Mar 27;26(13):3230–3238. doi: 10.1158/1078-0432.CCR-20-0168

Oncogenic genomic alterations, clinical phenotypes, and outcomes in metastatic castration-sensitive prostate cancer

Konrad H Stopsack ¹, Subhiksha Nandakumar ^2,^3,⁴, Andreas G Wibmer ⁵, Samuel Haywood ⁶, Emily S Weg ⁷, Ethan S Barnett ¹, Chloe J Kim ¹, Emily A Carbone ¹, Samantha E Vasselman ¹, Bastien Nguyen ^2,^3,⁴, Melanie A Hullings ¹, Howard I Scher ^1,⁸, Michael J Morris ^1,⁸, David B Solit ^1,^2,^3,⁸, Nikolaus Schultz ^2,^3,⁴, Philip W Kantoff ^1,^8,^#, Wassim Abida ^1,^8,^#

PMCID: PMC7334067 NIHMSID: NIHMS1580358 PMID: 32220891

Abstract

Background:

The genomic underpinning of clinical phenotypes and outcomes in metastatic castration-sensitive prostate cancer is unclear.

Methods:

In patients with metastatic castration-sensitive prostate cancer at a tertiary referral center, clinical-grade targeted tumor sequencing was performed to quantify tumor DNA copy number alterations and alterations in predefined oncogenic signaling pathways. Disease volume was classified as high-volume (≥4 bone metastases or visceral metastases) vs. low-volume.

Results:

Among 424 patients (88% white), 213 (50%) had high-volume disease and 211 (50%) had low-volume disease; 275 (65%) had de-novo metastatic disease and 149 (35%) had metastatic recurrence of non-metastatic disease. Rates of castration resistance (adjusted hazard ratio, 1.84; 95% CI, 1.40–2.41) and death (adjusted hazard ratio, 3.71; 95% CI, 2.28–6.02) were higher in high-volume disease. Tumors from high-volume disease had more copy number alterations. The NOTCH, cell cycle, and epigenetic modifiers pathways were the highest-ranking pathways enriched in high-volume disease. De-novo metastatic disease differed from metastatic recurrences in the prevalence of CDK12 alterations but had similar prognosis. Rates of castration resistance differed 1.5-fold to 5-fold according to alterations in AR, SPOP (inverse), and TP53, and the cell cycle, WNT (inverse), and MYC pathways, adjusting for disease volume and other genomic pathways. Overall survival rates differed 2-fold to 4-fold according to AR, SPOP (inverse), WNT (inverse), and cell cycle alterations. PI3K pathway alterations were not associated with prognosis once adjusted for other factors.

Conclusion:

This study identified genomic features associated with prognosis in metastatic castration-sensitive disease that may aid in molecular classification and treatment selection.

Keywords: prostate cancer, metastatic castration-sensitive, panel sequencing, genomic instability, oncogenic signaling pathways

Introduction

Treatment options for metastatic castration-sensitive prostate cancer are expanding (1). Both docetaxel and next-generation androgen receptor axis-directed therapies prolong overall survival (2–8). However, it is not clear which patients benefit most from intensified therapies, which increase toxicity and cost, or how clinical disease phenotypes can be used to find a drug class more likely to benefit a patient (1,9). Some but not all trials show more favorable outcomes with docetaxel for patients with high-volume disease, characterized by the presence of visceral metastases or high-risk bone metastases (2,10,11). Similarly, it has been suggested that patients who initially presented with de-novo metastases and those who developed metastatic recurrence after a diagnosis with localized disease may have differences in benefit from therapy (2,12).

The genomic underpinning of clinical phenotypes in metastatic castration-sensitive prostate cancer has not been elucidated to date. It is also incompletely understood which tumor DNA alterations are drivers of aggressiveness in prostate cancer (13,14), especially in castration-sensitive disease (1).

We set out to assess oncogenic alterations in tumor signaling pathways as the mechanistic basis of clinical phenotypes defined by disease volume and by timing of metastasis (de novo versus metastatic recurrence). We further aimed to determine which genomic alterations are associated with clinical outcomes in metastatic castration-sensitive prostate cancer. We addressed these questions using clinical-grade targeted tumor sequencing in a large cohort of patients with metastatic castration-sensitive prostate cancer.

Methods

Patient population and clinical characteristics

This study included patients with prostate cancer who underwent institutional review board-approved paired tumor–blood sequencing at a tertiary referral center after providing written informed consent. The study was conducted in accordance with the U.S. Common Rule. Patients had metastatic castration-sensitive disease at the time a specimen for genomic profiling was obtained. Disease extent had to be metastatic and before a potential future date of castration resistance. We first identified patients who had a tumor sample genomically profiled that had been confirmed as a primary or metastasis from prostate cancer by a pathologist. We set up a structured clinical research database for patient and sample characteristics, treatments, and clinical outcomes, including pilot testing for reliability and validity of team-based annotations. Data sources included pathology reports (primarily from re-review; if missing, external reports); patients’ self-reported race, ethnicity, and smoking status; and the medical record, drawing from medical oncology, urology, or radiation subspecialty documentation from the initial presentation at the cancer center as well as visits before and after obtaining a sample for genomic profiling. Castration resistance and metastasis were determined by the primary treating physicians; in cases of discrepancies, the record was reviewed by more than one team member. Extent of disease, sites of disease, and bone disease volume were reviewed by the study radiologist (A.G.W.) based primarily on bone scans and computed tomography. For high-volume disease, we used a modified definition, requiring presence of visceral metastases or at least four bone metastases, without requirements for extra-axial metastases unlike prior clinical trials (2,6,7); others were classified as low-volume disease. Additional imaging that had been obtained clinically was also reviewed for ambiguous cases.

Genomic profiling

For genomic profiling, both archival specimens or newly obtained specimens were formalin-fixed, and a peripheral blood sample was drawn as a source of germline DNA. Analysis of the germline sample was only performed in patients who signed a specific consent (15). The MSK-IMPACT panel, a hybridization capture-based clinical assay authorized by the Food and Drug Administration (FDA), was used to detect single-nucleotide variations, small insertions and deletions, copy number alterations, and structural rearrangements in 341 to 468 genes, depending on assay version (16). Clonality and allele-specific copy numbers were estimated using FACETS (17). Samples that had low tumor purity of 20% or less on histologic assessment or FACETS estimations, no detected somatic mutations, and no copy number alterations were excluded (6.7% overall; 4.1% of samples from metastatic castration-sensitive disease). If repeat samples during progression of metastatic castration-sensitive disease had been obtained (5% of patients), only the first sample was included.

As a measure of genomic instability, the burden of copy number alterations was inferred (fraction genome altered), also leveraging evenly distributed probes that tile common single nucleotide polymorphisms, and corrected for tumor purity (17). Tumor mutation burden was calculated as mutations per megabase. Potential actionability of tumor genomic alterations was annotated using OncoKB as of August 1, 2019 (18). Oncogenic alterations detected in the tumor and/or germline sample were grouped by major signaling pathways from pan-cancer analyses (19,20), excluding the HIPPO and TGF-β pathways that were altered in <5% of samples within clinical subgroups. TP53 was not grouped with DNA repair genes and considered separately, as were two individual genes relevant in prostate cancer (AR, SPOP).

Analysis

The primary pre-specified analysis of clinical phenotype (low-volume disease vs. high-volume disease and de novo vs. metastatic recurrence) compared fraction genome altered and prevalence of oncogenic alterations in key signaling pathways. Prevalence differences and ratios were estimated using binomial regression, convergence-assisted by Poisson models (21). We adjusted for predefined factors, including disease volume (in analyses of timing of metastases) or timing of metastases (in analyses of disease volume), origin of sample (prostate in the setting of metastatic disease vs. metastasis), age at sampling, time from metastasis to sample, and continuous exposure to androgen deprivation therapy. Our goal was valid quantification of genomic differences between clinical phenotypes, not decision making; confidence intervals (CIs) are not means for testing null hypotheses of no difference.

In a not hypothesis-driven exploratory analysis to probe for individual genes missed by pathway groupings, we compared prevalence of oncogenic gene alterations between phenotypes for genes that were altered in at least 5% of samples in any of the four clinical phenotype groups, using Fisher’s exact test for binomial proportions with a Benjamini-Hochberg false-discovery rate for multiple-testing correction.

To assess associations of clinical phenotypes (22,23) and pathway alterations with time to castration resistance as well as overall survival, we estimated hazard ratios (HRs) using Cox proportional hazards regression and differences in three-year restricted mean survival times (24). Follow-up started when the genomically profiled sample was obtained via biopsy, and patients without event were censored at the last clinic visit (for castration resistance) or at last contact (for overall survival). In a sensitivity analysis of pathways and prognosis, the top two most frequently altered genes per pathway (if altered in >2.5% of samples) were assessed individually.

Results

Study population

From 424 patients (median age at sample collection, 66 years; interquartile range, 59 to 72), a sample obtained while the patient had metastatic castration-sensitive disease was sequenced between May 2015 and September 2018 (Table 1). The majority of patients had de-novo metastatic disease (n = 275, 65%). Similar numbers of patients had low-volume disease and high-volume disease. As expected, patients with metastatic recurrences of initially non-metastatic disease, compared to those with de-novo metastatic disease, tended to be different in terms of age at sampling, PSA values at cancer diagnosis, disease volume, tissue sample, and continuous treatment with ADT (Table 1). Differences between patients with low-volume and high-volume disease were less pronounced, except for differences in profiled metastatic tissue (Table 1) due to the definition of high-volume disease. Median follow-up for development of castration resistance was 27.2 months and median follow-up for overall survival was 30.5 months.

Table 1. Patient and sample characteristics, by disease volume at genomic profiling and by timing of metastases.

Shown are counts (percentages across columns) or median [interquartile range].

		By disease volume		By timing of metastases
	All	Low-volume disease	High-volume disease	Metastatic recurrence	De-novo metastatic
	N=424	N=211	N=213	N=149	N=275
Age at sampling (years)	65.6 [59.0; 71.8]	65.3 [57.3; 71.1]	65.8 [60.7; 72.6]	68.3 [63.2; 74.4]	64.2 [57.1; 70.0]
Race
Asian	12 (4%)	7 (4%)	5 (3%)	1 (1%)	11 (5%)
Black/African American	27 (8%)	13 (7%)	14 (8%)	13 (10%)	14 (6%)
White	312 (88%)	155 (88%)	157 (88%)	111 (88%)	201 (89%)
Other	2 (0%)	1 (0%)	1 (0%)	1 (1%)	1 (0%)
(Missing)	71	35	36	23	48
Timing of metastases
Metastatic recurrence	149 (35%)	80 (38%)	69 (32%)	149 (100%)	0 (0%)
De-novo metastatic	275 (65%)	131 (62%)	144 (68%)	0 (0%)	275 (100%)
Disease volume
Low-volume disease	211 (50%)	211 (100%)	0 (0%)	80 (54%)	131 (48%)
High-volume disease	213 (50%)	0 (0%)	213 (100%)	69 (46%)	144 (52%)
Gleason grade at diagnosis
<7	19 (5%)	11 (6%)	8 (4%)	19 (14%)	0 (0%)
3+4	30 (8%)	16 (8%)	14 (7%)	25 (18%)	5 (2%)
4+3	55 (14%)	33 (17%)	22 (12%)	42 (30%)	13 (5%)
8	88 (23%)	44 (23%)	44 (23%)	27 (19%)	61 (25%)
9–10	192 (50%)	90 (46%)	102 (54%)	27 (19%)	165 (68%)
(Missing)	40	17	23	9	31
PSA at diagnosis (ng/ml)	17.2 [6.6; 88.8]	12.2 [6.0; 42.2]	29.2 [6.9; 257.7]	6.7 [4.5; 11.0]	46.6 [12.7; 245.8]
Sample tissue
Bone	61 (14%)	38 (18%)	23 (11%)	35 (23%)	26 (9%)
Liver	15 (4%)	0 (0%)	15 (7%)	7 (5%)	8 (3%)
Lung	26 (6%)	0 (0%)	26 (12%)	21 (14%)	5 (2%)
Lymph node	93 (22%)	65 (31%)	28 (13%)	52 (35%)	41 (15%)
Other soft tissue	25 (6%)	3 (1%)	22 (10%)	21 (14%)	4 (1%)
Prostate	204 (48%)	105 (50%)	99 (46%)	13 (9%)	191 (69%)
On continuous ADT	91 (22%)	49 (23%)	42 (20%)	53 (36%)	38 (14%)

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PSA, prostate-specific antigen; ADT, androgen-deprivation therapy.

Clinical phenotypes and prognosis

Of 213 patients with high-volume disease, 139 developed castration resistance, compared to 101 of the 211 patients with low-volume disease (adjusted HR, 1.84; 95% CI, 1.40 to 2.41; Figure 1A). Disease volume was even more strongly associated with overall survival, with 77 deaths among patients with high-volume disease compared to 25 deaths among patients with low-volume disease (adjusted HR, 3.71; 95% CI, 2.28 to 6.02; Figure 1B). Over 36 months (three years) of follow up, patients with high-volume disease lived, on average, 4.8 months shorter (95% CI, 3.3 to 6.3) than patients with low-volume disease.

Figure 1. — Clinical phenotypes and outcomes. Kaplan-Meier curves by disease volume (low-volume *vs.* high-volume disease; panels A, B) and by timing of metastases (metastatic recurrence *vs. de-novo* metastases; panels C, D) for time to castration resistant prostate cancer (CRPC, A, C) and overall survival (B, D). Shaded areas denote 95% confidence intervals (CIs) for survival functions; hazard ratios (HRs) are from Cox regression models. Adjusted models include timing of metastases (for models of disease volume) or disease volume (for models of timing of metastases) as well as age at sampling, time from diagnosis to sampling, time from metastasis to sampling, and PSA at cancer diagnosis.

Associations between timing of metastases and prognosis were weaker. Of 275 patients with de-novo metastatic disease, 175 developed castration resistance, compared to 65 of the 149 patients with metastatic recurrence. Timing of metastases was associated with development of castration resistance when adjusting for age at sampling, disease volume, and time from metastasis to sample (HR, 1.52; 95% CI, 1.11 to 2.10). However, timing of metastases was not prognostic once accounting for higher PSA at diagnosis and time since initial diagnosis (HR, 0.87; 95% CI, 0.53 to 1.43; Figure 1C). There were 78 deaths among patients with de-novo metastatic disease compared to 24 deaths among patients with metastatic recurrences (adjusted HR, 0.95; 95% CI, 0.41 to 2.21; Figure 1D).

Genomics and clinical phenotypes

The burden of copy number alterations, a consequence of genomic instability and measured as fraction genome altered (median, 32%; interquartile range, 24 to 48), was higher in high-volume disease than in low-volume disease (adjusted mean difference in percentage points, 4.6; 95% CI, 1.5 to 7.7; Figure 2). Fraction genome altered was similar between metastatic-recurrent and de-novo metastatic disease (adjusted mean difference in percentage points, 1.1; 95% CI, −3.1 to 5.2; Figure 2). As expected in non-castration-resistant prostate cancer, tumor mutation burden was mostly low (median, 2.6; interquartile range, 1.8 to 4.4) and similar across clinical phenotypes (Suppl. Table 1). Tumors had a median of 3 oncogenic alterations (interquartile range, 2 to 5; Suppl. Figure 1). 211 tumors (50%) had at least one potentially actionable alteration (Suppl. Figure 2).

Figure 2. — Fraction genome altered, the proportion of genes with copy number alterations and a consequence of genomic instability, is compared by clinical phenotypes (with unadjusted mean group difference and 95% CI). Thick lines indicates medians, boxes span interquartile ranges.

To assess oncogenic alterations in biologically-grounded pathways as a potential basis of clinical phenotypes, 144 genes were grouped into 11 pathways (Suppl. Table 2, Suppl. Table 3). In high-volume disease, for example, alterations in the NOTCH pathway were 4.2 percentage points more common (95% CI, 0.1 to 8.3; Figure 3A); the next-ranked candidate pathways were the cell cycle and the epigenetic modifiers pathways. Results persisted when adjusting for modest differences in tumor purity or sequencing depth across clinical phenotypes, particularly by timing of metastases (Suppl. Table 1, Suppl. Figure 3, Suppl. Figure 4).

In comparisons by timing of metastatic disease (Figure 3B), AR alterations were 8.6 percentage points (95% CI, 3.3 to 13.8) more frequent in metastatic recurrences than in de-novo metastatic disease. However, this association was null once adjusted for continuous ADT treatment at the time of sampling. Alterations in SPOP and the cell cycle and NOTCH pathways were less common in de-novo metastatic disease, but results were imprecise.

There were no single genes differentially altered by volume of disease (Suppl. Figure 5, Suppl. Table 4). CDK12 alterations were 6.7 percentage points (95% CI, 3.0 to 10.4) more common in de-novo metastatic disease compared to metastatic recurrence (false discovery rate, 0.037, Suppl. Table 5).

Genomic alterations and prognosis

Rates of progression to castration resistance were 1.6-fold to 5-fold higher with alterations in AR and TP53 as well as the cell cycle and MYC pathways and approximately 1.5-fold lower with SPOP and WNT pathway alterations (Figure 4A, right panels). Associations persisted in a multivariable model that also adjusted for alterations in all other pathways (Figure 4A, right panels). Over 36 months of follow-up, on average, patients with pathway alterations had 6 to 11 months shorter (AR, cell cycle, MYC, TP53) and 2 to 5 months longer times to castration resistance (WNT, SPOP; Figure 4A, left panel; Suppl. Table 6).

Overall survival rates (Figure 4B, right panels) differed 2-fold to 4-fold according to alterations in AR, SPOP (inverse), and the cell cycle and WNT (inverse) pathways. Over 36 months of follow-up, differences in average survival were between 1 to 4 months (Figure 4B, left panel).

A potential association between TP53 alterations and overall survival was attenuated in a multivariable model, as were associations of NOTCH pathway alterations with castration resistance; estimates for overall survival were imprecise. Notably, associations of alterations in DNA repair, PI3K, RAS/RAF/MAPK, and epigenetic modifiers pathways with castration resistance and overall survival were null, particularly in multivariable models (Figure 4). In a post-hoc sensitivity analysis, assessing the most commonly altered genes of each pathway (Suppl. Figure 6), results were generally consistent. For BRCA2 alterations, results were compatible with higher rates of castration resistance (adjusted HR, 1.60; 95% CI, 0.98 to 2.63); associations with overall survival could not be ruled out (adjusted HR, 1.08; 95% CI, 0.50 to 2.33). PTEN alterations were associated with a worse prognosis only if assessed in isolation; in multivariable models, there were no strong associations with castration resistance (adjusted HR, 1.27; 95% CI, 0.94 to 1.73) and overall survival (adjusted HR, 0.95; 95% CI, 0.58 to 1.56).

Discussion

In this large clinical-grade sequencing study of paired tumor–blood samples from patients with metastatic castration-sensitive prostate cancer, we identified genomic characteristics of high-volume disease and genomic characteristics of tumors with inferior prognosis. Tumors from high-volume disease had a higher fraction genome altered indicative of genomic instability, more oncogenic alterations in the NOTCH, cell cycle, and potentially epigenetic modifiers pathways, and an inferior prognosis compared to low-volume disease. We were unable to detect unequivocal differences between de-novo metastatic disease and recurrent metastatic disease in both clinical outcomes and genomics, except for more frequent CDK12 alterations in de-novo metastatic disease. Importantly, we demonstrate that specific oncogenic signaling pathways are associated with two major clinical endpoints in metastatic castration-sensitive prostate cancer, castration resistance and overall survival. Alterations in AR, TP53 and the cell cycle and MYC pathways occurred in tumors with worse prognosis, while tumors with SPOP and WNT pathway alterations had better prognosis.

Genomic “landscape” studies of tumor DNA profiling in prostate cancer generally excluded metastatic castration-sensitive tumors, focusing on localized disease (25–30) or metastatic castration-resistant disease (13,31–37). Exceptions are two smaller studies (14,15) and a study that included archival castration-naïve tumors only from patients who developed castration-resistant disease (38). We connected genomics with clinical phenotypes and clinical outcomes in castration-sensitive disease. Differences between high-volume and low-volume disease in genomic instability, a poor prognostic factor at least in early prostate cancer (39,40), may explain some of the differences in prognosis by disease volume, yet they are currently difficult to address therapeutically. Our focus on well-defined oncogenic signaling pathways (19) suggested some potentially better targets for the high-volume disease, a subgroup that has long been recognized to have inferior prognosis (22). Oncogenic alterations in single genes of the NOTCH pathway, such as SPEN (34), were individually uncommon, yet our analysis suggests this pathway as one potential driver of high-volume disease. NOTCH alterations have been suggested as a determinant of resistance to docetaxel (41), a therapy that some clinicians recommend just for patients with high-volume disease. Overall, it is critical that differences in pathway alteration prevalence be validated in future tumor sequencing studies. More precise estimates are particularly needed for additional candidates, such as the epigenetic modifiers pathway, SPOP, and CDK12, which emerged in a gene-level discovery effort. Future studies, which may need to be an order of magnitude larger, should also assess how genomic alterations differ by specific metastatic site, a distinction that a “volume” definition obscures.

De novo metastatic disease was associated with modestly inferior outcomes in unadjusted analyses compared to metastatic recurrences. Surprisingly however, once we accounted for systematic differences between patients who were diagnosed with metastatic prostate cancer de-novo and those who experienced metastatic recurrence of initially non-metastatic disease, we were unable to detect prognostic differences. The relatively small number of metastatic recurrences made results imprecise, and systematic differences between patient groups may have obscured true differences in genomics. Nonetheless, our data suggest that the timing of metastasis is likely not a strong prognostic factor in metastatic castration-sensitive disease, and differential treatment just based on this clinical feature may not be needed.

Genomic alterations that characterized tumors with poor prognosis did not appear to be created equal. AR alterations, while uncommon in the metastatic castration-sensitive setting, were the strongest predictor of development of castration resistance and death. Relatively strong associations between cell cycle and MYC pathways, as well as SPOP and TP53 alterations, with prognosis in this disease state are concordant with observations in metastatic castration-resistant prostate cancer (13). However, WNT pathway alterations were associated with better prognosis, including longer overall survival when accounting for clinical factors and other genomic alterations. This observation is in contrast to two smaller studies in metastatic castration-resistant prostate cancer (37,42), where WNT pathway alterations, including CTNNB1, were associated with worse prognosis.

DNA repair and PI3K pathway alterations had weak to modest associations with development of castration resistance when assessed in isolation. Neither pathway remained associated with clinical outcomes once accounting for other genomic features and clinical factors. It is possible that specific alterations summarized in the DNA repair pathway could be drivers of poor prognosis, such as BRCA2. For the PI3K pathway and PTEN alterations, our data suggest no strong associations with disease progression and overall survival in this disease state, consistent with results in castration-resistant disease (13).

This study shares its main limitation with all other tumor sequencing studies published on prostate cancer to date (13–15,25–38) in that it was hospital-based, relying on patients seen at an academic referral center. It is widely appreciated that such study populations are not representative of patients nationally or globally (affecting generalizability). Perhaps more importantly, such a restriction may also introduce selection bias (affecting validity) that is difficult to address analytically, particularly since only a subset of patients undergoes tumor biopsies. An important next step will be to nest studies of the tumor genome in ongoing population-based cohort studies with tumor biorepositories that can address these issues. With evolving sequencing technologies, future studies will also explore the cancer genome more broadly, complementary to our approach that concentrated on deep-coverage sequencing of known cancer susceptibility genes with curated functional annotation.

Taken together, our study takes the first step towards a genomic classification of metastatic castration-sensitive prostate cancer. In describing some of the genomic alterations that occurred more frequently in high-volume disease, we highlight how specific oncogenic signaling pathways may be a potentially targetable biologic underpinning of this poor-prognosis subtype. Our results on prognostically relevant genomic pathways highlight potential drivers of disease progression that may help prioritization in developing targeted therapies and that could be targeted in studies of intensified upfront therapy.

Data availability

Genomic and clinical data are available at https://www.cbioportal.org/study/summary?id=prad_mcspc_mskcc_2020

Supplementary Material

NIHMS1580358-supplement-1.html^{(3.9MB, html)}

NIHMS1580358-supplement-2.zip^{(188.7KB, zip)}

Translational Relevance.

The genomic landscape of metastatic castration-sensitive prostate cancer is not well defined, and disease stratification for the purpose of initial treatment selection has primarily relied on clinical phenotypes, including volume of disease at the time of metastasis. Here, we describe tumor genomics in a large cohort of patients with metastatic castration-sensitive prostate cancer and show genomic features that are associated with clinical phenotypes, including with disease volume. We identify genomic alterations that are associated with prognosis in metastatic castration-sensitive disease (overall survival and time to castration resistance), demonstrating that alterations in AR, TP53 and the cell cycle and MYC pathways occur in tumors with worse prognosis, while alterations in SPOP and the WNT pathway occur in tumors with better prognosis. Our findings may aid in molecular classification of metastatic castration-sensitive prostate cancer, and pathways that are prognostically relevant could be targeted in studies of intensified upfront therapy.

Funding:

This work was funded in part by a National Cancer Institute Cancer Center Support Grant (P30CA008748) and Prostate Cancer SPORE (P50CA092629), the Department of Defense (Early Investigator Research Award W81XWH-18-1-0330 to K.H.S.; Physician Research Award W81XWH-17-1-0124 to W.A.), and the Marie-Josée and Henry R. Kravis Center for Molecular Oncology. K.H.S., N.S., and W.A. are Prostate Cancer Foundation Young Investigators.

Footnotes

Conflicts of Interest

H.S.: Consultancy/Advisory Board: Ambry Genetics Corporation, Konica Minolta, Inc. (compensated), WCG Oncology Advisory Board (compensated), Amgen (uncompensated), Bayer (Uncompensated) ESSA Pharma Inc (uncompensated), Janssen Research & Development, LLC (Uncompensated), Janssen Biotech, Inc. (Uncompensated), OncLive Insights (Compensated), Menarini Silicon Biosystems (Uncompensated), Physicians Education Resource (Compensated), Sanofi Aventis (Uncompensated), Research funding: Epic Sciences, Janssen, Menarini Silicon Biosystemis, ThermoFisher Scientific, Travel, Accomodations, Expenses: Amgen, ESSA Pharma Inc., Genome Profiling, LLC, Menarini Silicon Biosystems, OncLive Insights, Physician Education Resource, Sanofi Aventis, WCG Oncology

M.J.M.: Unpaid consultant: Astellas, Bayer, Endocyte; Paid consultant: Advanced Accelerator Applications, Blue Earth Diagnostics, Tokai, Tolmar, Oric; Institutional research funding: Bayer, Sanofi, Endocyte, Progenics, Corcept, Roche/Genentech

D.B.S.: Consulting or honoraria from Pfizer, Loxo Oncology, Lilly Oncology, Illumina and Vivideon Therapeutics.

P.W.K.: Investment in Context Therapeutics LLC, DRGT, Placon, Seer Biosciences, and Tarveda Therapeutics. Company board member for Context Therapeutics LLC. Consultant/scientific advisory board member for Bavarian Nordic Immunotherapeutics, DRGT, GE Healthcare, Janssen, New England Research Institutes, Inc., OncoCellMDX, Progenity, Sanofi, Seer Biosciences, Tarveda Therapeutics, and Thermo Fisher. Data safety monitoring boards for Genentech/Roche and Merck.

W.A.: Consulting for Clovis Oncology, Janssen Pharmaceutica, MORE Health and ORIC Pharmaceuticals. Research funding from AstraZeneca, Zenith Epigenetics, Clovis Oncology and GlaxoSmithKline. Travel from Clovis Oncology, GlaxoSmithKline, and ORIC Pharmaceuticals.

All other authors disclose no conflicts of interest.

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10.Gravis G, Boher JM, Chen YH, Liu G, Fizazi K, Carducci MA, et al. Burden of Metastatic Castrate Naive Prostate Cancer Patients, to Identify Men More Likely to Benefit from Early Docetaxel: Further Analyses of CHAARTED and GETUG-AFU15 Studies. Eur Urol 2018;73(6):847–55 doi 10.1016/j.eururo.2018.02.001. [DOI] [PMC free article] [PubMed] [Google Scholar]
11.Clarke NW, Ali A, Ingleby FC, Hoyle A, Amos CL, Attard G, et al. Addition of docetaxel to hormonal therapy in low- and high-burden metastatic hormone sensitive prostate cancer: long-term survival results from the STAMPEDE trial. Ann Oncol 2019;30(12):1992–2003 doi 10.1093/annonc/mdz396. [DOI] [PMC free article] [PubMed] [Google Scholar]
12.Finianos A, Gupta K, Clark B, Simmens SJ, Aragon-Ching JB. Characterization of Differences Between Prostate Cancer Patients Presenting With De Novo Versus Primary Progressive Metastatic Disease. Clin Genitourin Cancer 2018;16(1):85–9 doi 10.1016/j.clgc.2017.08.006. [DOI] [PubMed] [Google Scholar]
13.Abida W, Cyrta J, Heller G, Prandi D, Armenia J, Coleman I, et al. Genomic correlates of clinical outcome in advanced prostate cancer. Proc Natl Acad Sci U S A 2019;116(23):11428–36 doi 10.1073/pnas.1902651116. [DOI] [PMC free article] [PubMed] [Google Scholar]
14.Hamid AA, Gray KP, Shaw G, MacConaill LE, Evan C, Bernard B, et al. Compound Genomic Alterations of TP53, PTEN, and RB1 Tumor Suppressors in Localized and Metastatic Prostate Cancer. Eur Urol 2019;76(1):89–97 doi 10.1016/j.eururo.2018.11.045. [DOI] [PubMed] [Google Scholar]
15.Abida W, Armenia J, Gopalan A, Brennan R, Walsh M, Barron D, et al. Prospective Genomic Profiling of Prostate Cancer Across Disease States Reveals Germline and Somatic Alterations That May Affect Clinical Decision Making. JCO Precis Oncol 2017;2017 doi 10.1200/PO.17.00029. [DOI] [PMC free article] [PubMed] [Google Scholar]
16.Cheng DT, Mitchell TN, Zehir A, Shah RH, Benayed R, Syed A, et al. Memorial Sloan Kettering-Integrated Mutation Profiling of Actionable Cancer Targets (MSK-IMPACT): A Hybridization Capture-Based Next-Generation Sequencing Clinical Assay for Solid Tumor Molecular Oncology. J Mol Diagn 2015;17(3):251–64 doi 10.1016/j.jmoldx.2014.12.006. [DOI] [PMC free article] [PubMed] [Google Scholar]
17.Shen R, Seshan VE. FACETS: allele-specific copy number and clonal heterogeneity analysis tool for high-throughput DNA sequencing. Nucleic Acids Res 2016;44(16):e131 doi 10.1093/nar/gkw520. [DOI] [PMC free article] [PubMed] [Google Scholar]
18.Chakravarty D, Gao J, Phillips SM, Kundra R, Zhang H, Wang J, et al. OncoKB: A Precision Oncology Knowledge Base. JCO Precis Oncol 2017;2017 doi 10.1200/PO.17.00011. [DOI] [PMC free article] [PubMed] [Google Scholar]
19.Sanchez-Vega F, Mina M, Armenia J, Chatila WK, Luna A, La KC, et al. Oncogenic Signaling Pathways in The Cancer Genome Atlas. Cell 2018;173(2):321–37 e10 doi 10.1016/j.cell.2018.03.035. [DOI] [PMC free article] [PubMed] [Google Scholar]
20.Knijnenburg TA, Wang L, Zimmermann MT, Chambwe N, Gao GF, Cherniack AD, et al. Genomic and Molecular Landscape of DNA Damage Repair Deficiency across The Cancer Genome Atlas. Cell Rep 2018;23(1):239–54 e6 doi 10.1016/j.celrep.2018.03.076. [DOI] [PMC free article] [PubMed] [Google Scholar]
21.Spiegelman D, Hertzmark E. Easy SAS calculations for risk or prevalence ratios and differences. Am J Epidemiol 2005;162(3):199–200 doi 10.1093/aje/kwi188. [DOI] [PubMed] [Google Scholar]
22.Crawford ED, Eisenberger MA, McLeod DG, Spaulding JT, Benson R, Dorr FA, et al. A controlled trial of leuprolide with and without flutamide in prostatic carcinoma. N Engl J Med 1989;321(7):419–24 doi 10.1056/NEJM198908173210702. [DOI] [PubMed] [Google Scholar]
23.Francini E, Gray KP, Xie W, Shaw GK, Valenca L, Bernard B, et al. Time of metastatic disease presentation and volume of disease are prognostic for metastatic hormone sensitive prostate cancer (mHSPC). Prostate 2018;78(12):889–95 doi 10.1002/pros.23645. [DOI] [PMC free article] [PubMed] [Google Scholar]
24.Trinquart L, Bill-Axelson A, Rider JR. Restricted Mean Survival Times to Improve Communication of Evidence from Cancer Randomized Trials and Observational Studies. Eur Urol 2019;76(2):137–9 doi 10.1016/j.eururo.2019.04.002. [DOI] [PubMed] [Google Scholar]
25.Cancer Genome Atlas Research Network. The Molecular Taxonomy of Primary Prostate Cancer. Cell 2015;163(4):1011–25 doi 10.1016/j.cell.2015.10.025. [DOI] [PMC free article] [PubMed] [Google Scholar]
26.Barbieri CE, Baca SC, Lawrence MS, Demichelis F, Blattner M, Theurillat JP, et al. Exome sequencing identifies recurrent SPOP, FOXA1 and MED12 mutations in prostate cancer. Nat Genet 2012;44(6):685–9 doi 10.1038/ng.2279. [DOI] [PMC free article] [PubMed] [Google Scholar]
27.Beltran H, Wyatt AW, Chedgy EC, Donoghue A, Annala M, Warner EW, et al. Impact of Therapy on Genomics and Transcriptomics in High-Risk Prostate Cancer Treated with Neoadjuvant Docetaxel and Androgen Deprivation Therapy. Clin Cancer Res 2017;23(22):6802–11 doi 10.1158/1078-0432.CCR-17-1034. [DOI] [PMC free article] [PubMed] [Google Scholar]
28.Fraser M, Sabelnykova VY, Yamaguchi TN, Heisler LE, Livingstone J, Huang V, et al. Genomic hallmarks of localized, non-indolent prostate cancer. Nature 2017;541(7637):359–64 doi 10.1038/nature20788. [DOI] [PubMed] [Google Scholar]
29.Wedge DC, Gundem G, Mitchell T, Woodcock DJ, Martincorena I, Ghori M, et al. Sequencing of prostate cancers identifies new cancer genes, routes of progression and drug targets. Nat Genet 2018;50(5):682–92 doi 10.1038/s41588-018-0086-z. [DOI] [PMC free article] [PubMed] [Google Scholar]
30.Gerhauser C, Favero F, Risch T, Simon R, Feuerbach L, Assenov Y, et al. Molecular Evolution of Early-Onset Prostate Cancer Identifies Molecular Risk Markers and Clinical Trajectories. Cancer Cell 2018;34(6):996–1011 e8 doi 10.1016/j.ccell.2018.10.016. [DOI] [PMC free article] [PubMed] [Google Scholar]
31.Robinson D, Van Allen EM, Wu YM, Schultz N, Lonigro RJ, Mosquera JM, et al. Integrative clinical genomics of advanced prostate cancer. Cell 2015;161(5):1215–28 doi 10.1016/j.cell.2015.05.001. [DOI] [PMC free article] [PubMed] [Google Scholar]
32.Kumar A, Coleman I, Morrissey C, Zhang X, True LD, Gulati R, et al. Substantial interindividual and limited intraindividual genomic diversity among tumors from men with metastatic prostate cancer. Nat Med 2016;22(4):369–78 doi 10.1038/nm.4053. [DOI] [PMC free article] [PubMed] [Google Scholar]
33.Grasso CS, Wu YM, Robinson DR, Cao X, Dhanasekaran SM, Khan AP, et al. The mutational landscape of lethal castration-resistant prostate cancer. Nature 2012;487(7406):239–43 doi 10.1038/nature11125. [DOI] [PMC free article] [PubMed] [Google Scholar]
34.Armenia J, Wankowicz SAM, Liu D, Gao J, Kundra R, Reznik E, et al. The long tail of oncogenic drivers in prostate cancer. Nat Genet 2018;50(5):645–51 doi 10.1038/s41588-018-0078-z. [DOI] [PMC free article] [PubMed] [Google Scholar]
35.Beltran H, Prandi D, Mosquera JM, Benelli M, Puca L, Cyrta J, et al. Divergent clonal evolution of castration-resistant neuroendocrine prostate cancer. Nat Med 2016;22(3):298–305 doi 10.1038/nm.4045. [DOI] [PMC free article] [PubMed] [Google Scholar]
36.Quigley DA, Dang HX, Zhao SG, Lloyd P, Aggarwal R, Alumkal JJ, et al. Genomic Hallmarks and Structural Variation in Metastatic Prostate Cancer. Cell 2018;174(3):758–69 e9 doi 10.1016/j.cell.2018.06.039. [DOI] [PMC free article] [PubMed] [Google Scholar]
37.Chen WS, Aggarwal R, Zhang L, Zhao SG, Thomas GV, Beer TM, et al. Genomic Drivers of Poor Prognosis and Enzalutamide Resistance in Metastatic Castration-resistant Prostate Cancer. Eur Urol 2019;76(5):562–71 doi 10.1016/j.eururo.2019.03.020. [DOI] [PMC free article] [PubMed] [Google Scholar]
38.Mateo J, Seed G, Bertan C, Rescigno P, Dolling D, Figueiredo I, et al. Genomics of lethal prostate cancer at diagnosis and castration resistance. J Clin Invest 2020. doi 10.1172/JCI132031. [DOI] [PMC free article] [PubMed] [Google Scholar]
39.Hieronymus H, Murali R, Tin A, Yadav K, Abida W, Moller H, et al. Tumor copy number alteration burden is a pan-cancer prognostic factor associated with recurrence and death. Elife 2018;7 doi 10.7554/eLife.37294. [DOI] [PMC free article] [PubMed] [Google Scholar]
40.Stopsack KH, Whittaker CA, Gerke TA, Loda M, Kantoff PW, Mucci LA, et al. Aneuploidy drives lethal progression in prostate cancer. Proc Natl Acad Sci U S A 2019;116(23):11390–5 doi 10.1073/pnas.1902645116. [DOI] [PMC free article] [PubMed] [Google Scholar]
41.Domingo-Domenech J, Vidal SJ, Rodriguez-Bravo V, Castillo-Martin M, Quinn SA, Rodriguez-Barrueco R, et al. Suppression of acquired docetaxel resistance in prostate cancer through depletion of notch- and hedgehog-dependent tumor-initiating cells. Cancer Cell 2012;22(3):373–88 doi 10.1016/j.ccr.2012.07.016. [DOI] [PMC free article] [PubMed] [Google Scholar]
42.Wang L, Dehm SM, Hillman DW, Sicotte H, Tan W, Gormley M, et al. A prospective genome-wide study of prostate cancer metastases reveals association of wnt pathway activation and increased cell cycle proliferation with primary resistance to abiraterone acetate-prednisone. Ann Oncol 2018;29(2):352–60 doi 10.1093/annonc/mdx689. [DOI] [PMC free article] [PubMed] [Google Scholar]

Associated Data

This section collects any data citations, data availability statements, or supplementary materials included in this article.

Supplementary Materials

NIHMS1580358-supplement-1.html^{(3.9MB, html)}

NIHMS1580358-supplement-2.zip^{(188.7KB, zip)}

Data Availability Statement

Genomic and clinical data are available at https://www.cbioportal.org/study/summary?id=prad_mcspc_mskcc_2020

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[R9] 9.Gillessen S, Attard G, Beer TM, Beltran H, Bossi A, Bristow R, et al. Management of Patients with Advanced Prostate Cancer: The Report of the Advanced Prostate Cancer Consensus Conference APCCC 2017. Eur Urol 2018;73(2):178–211 doi 10.1016/j.eururo.2017.06.002. [DOI] [PubMed] [Google Scholar]

[R10] 10.Gravis G, Boher JM, Chen YH, Liu G, Fizazi K, Carducci MA, et al. Burden of Metastatic Castrate Naive Prostate Cancer Patients, to Identify Men More Likely to Benefit from Early Docetaxel: Further Analyses of CHAARTED and GETUG-AFU15 Studies. Eur Urol 2018;73(6):847–55 doi 10.1016/j.eururo.2018.02.001. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R11] 11.Clarke NW, Ali A, Ingleby FC, Hoyle A, Amos CL, Attard G, et al. Addition of docetaxel to hormonal therapy in low- and high-burden metastatic hormone sensitive prostate cancer: long-term survival results from the STAMPEDE trial. Ann Oncol 2019;30(12):1992–2003 doi 10.1093/annonc/mdz396. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R12] 12.Finianos A, Gupta K, Clark B, Simmens SJ, Aragon-Ching JB. Characterization of Differences Between Prostate Cancer Patients Presenting With De Novo Versus Primary Progressive Metastatic Disease. Clin Genitourin Cancer 2018;16(1):85–9 doi 10.1016/j.clgc.2017.08.006. [DOI] [PubMed] [Google Scholar]

[R13] 13.Abida W, Cyrta J, Heller G, Prandi D, Armenia J, Coleman I, et al. Genomic correlates of clinical outcome in advanced prostate cancer. Proc Natl Acad Sci U S A 2019;116(23):11428–36 doi 10.1073/pnas.1902651116. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R14] 14.Hamid AA, Gray KP, Shaw G, MacConaill LE, Evan C, Bernard B, et al. Compound Genomic Alterations of TP53, PTEN, and RB1 Tumor Suppressors in Localized and Metastatic Prostate Cancer. Eur Urol 2019;76(1):89–97 doi 10.1016/j.eururo.2018.11.045. [DOI] [PubMed] [Google Scholar]

[R15] 15.Abida W, Armenia J, Gopalan A, Brennan R, Walsh M, Barron D, et al. Prospective Genomic Profiling of Prostate Cancer Across Disease States Reveals Germline and Somatic Alterations That May Affect Clinical Decision Making. JCO Precis Oncol 2017;2017 doi 10.1200/PO.17.00029. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R16] 16.Cheng DT, Mitchell TN, Zehir A, Shah RH, Benayed R, Syed A, et al. Memorial Sloan Kettering-Integrated Mutation Profiling of Actionable Cancer Targets (MSK-IMPACT): A Hybridization Capture-Based Next-Generation Sequencing Clinical Assay for Solid Tumor Molecular Oncology. J Mol Diagn 2015;17(3):251–64 doi 10.1016/j.jmoldx.2014.12.006. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R17] 17.Shen R, Seshan VE. FACETS: allele-specific copy number and clonal heterogeneity analysis tool for high-throughput DNA sequencing. Nucleic Acids Res 2016;44(16):e131 doi 10.1093/nar/gkw520. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R18] 18.Chakravarty D, Gao J, Phillips SM, Kundra R, Zhang H, Wang J, et al. OncoKB: A Precision Oncology Knowledge Base. JCO Precis Oncol 2017;2017 doi 10.1200/PO.17.00011. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R19] 19.Sanchez-Vega F, Mina M, Armenia J, Chatila WK, Luna A, La KC, et al. Oncogenic Signaling Pathways in The Cancer Genome Atlas. Cell 2018;173(2):321–37 e10 doi 10.1016/j.cell.2018.03.035. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R20] 20.Knijnenburg TA, Wang L, Zimmermann MT, Chambwe N, Gao GF, Cherniack AD, et al. Genomic and Molecular Landscape of DNA Damage Repair Deficiency across The Cancer Genome Atlas. Cell Rep 2018;23(1):239–54 e6 doi 10.1016/j.celrep.2018.03.076. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R21] 21.Spiegelman D, Hertzmark E. Easy SAS calculations for risk or prevalence ratios and differences. Am J Epidemiol 2005;162(3):199–200 doi 10.1093/aje/kwi188. [DOI] [PubMed] [Google Scholar]

[R22] 22.Crawford ED, Eisenberger MA, McLeod DG, Spaulding JT, Benson R, Dorr FA, et al. A controlled trial of leuprolide with and without flutamide in prostatic carcinoma. N Engl J Med 1989;321(7):419–24 doi 10.1056/NEJM198908173210702. [DOI] [PubMed] [Google Scholar]

[R23] 23.Francini E, Gray KP, Xie W, Shaw GK, Valenca L, Bernard B, et al. Time of metastatic disease presentation and volume of disease are prognostic for metastatic hormone sensitive prostate cancer (mHSPC). Prostate 2018;78(12):889–95 doi 10.1002/pros.23645. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R24] 24.Trinquart L, Bill-Axelson A, Rider JR. Restricted Mean Survival Times to Improve Communication of Evidence from Cancer Randomized Trials and Observational Studies. Eur Urol 2019;76(2):137–9 doi 10.1016/j.eururo.2019.04.002. [DOI] [PubMed] [Google Scholar]

[R25] 25.Cancer Genome Atlas Research Network. The Molecular Taxonomy of Primary Prostate Cancer. Cell 2015;163(4):1011–25 doi 10.1016/j.cell.2015.10.025. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R26] 26.Barbieri CE, Baca SC, Lawrence MS, Demichelis F, Blattner M, Theurillat JP, et al. Exome sequencing identifies recurrent SPOP, FOXA1 and MED12 mutations in prostate cancer. Nat Genet 2012;44(6):685–9 doi 10.1038/ng.2279. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R27] 27.Beltran H, Wyatt AW, Chedgy EC, Donoghue A, Annala M, Warner EW, et al. Impact of Therapy on Genomics and Transcriptomics in High-Risk Prostate Cancer Treated with Neoadjuvant Docetaxel and Androgen Deprivation Therapy. Clin Cancer Res 2017;23(22):6802–11 doi 10.1158/1078-0432.CCR-17-1034. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R28] 28.Fraser M, Sabelnykova VY, Yamaguchi TN, Heisler LE, Livingstone J, Huang V, et al. Genomic hallmarks of localized, non-indolent prostate cancer. Nature 2017;541(7637):359–64 doi 10.1038/nature20788. [DOI] [PubMed] [Google Scholar]

[R29] 29.Wedge DC, Gundem G, Mitchell T, Woodcock DJ, Martincorena I, Ghori M, et al. Sequencing of prostate cancers identifies new cancer genes, routes of progression and drug targets. Nat Genet 2018;50(5):682–92 doi 10.1038/s41588-018-0086-z. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R30] 30.Gerhauser C, Favero F, Risch T, Simon R, Feuerbach L, Assenov Y, et al. Molecular Evolution of Early-Onset Prostate Cancer Identifies Molecular Risk Markers and Clinical Trajectories. Cancer Cell 2018;34(6):996–1011 e8 doi 10.1016/j.ccell.2018.10.016. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R31] 31.Robinson D, Van Allen EM, Wu YM, Schultz N, Lonigro RJ, Mosquera JM, et al. Integrative clinical genomics of advanced prostate cancer. Cell 2015;161(5):1215–28 doi 10.1016/j.cell.2015.05.001. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R32] 32.Kumar A, Coleman I, Morrissey C, Zhang X, True LD, Gulati R, et al. Substantial interindividual and limited intraindividual genomic diversity among tumors from men with metastatic prostate cancer. Nat Med 2016;22(4):369–78 doi 10.1038/nm.4053. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R33] 33.Grasso CS, Wu YM, Robinson DR, Cao X, Dhanasekaran SM, Khan AP, et al. The mutational landscape of lethal castration-resistant prostate cancer. Nature 2012;487(7406):239–43 doi 10.1038/nature11125. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R34] 34.Armenia J, Wankowicz SAM, Liu D, Gao J, Kundra R, Reznik E, et al. The long tail of oncogenic drivers in prostate cancer. Nat Genet 2018;50(5):645–51 doi 10.1038/s41588-018-0078-z. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R35] 35.Beltran H, Prandi D, Mosquera JM, Benelli M, Puca L, Cyrta J, et al. Divergent clonal evolution of castration-resistant neuroendocrine prostate cancer. Nat Med 2016;22(3):298–305 doi 10.1038/nm.4045. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R36] 36.Quigley DA, Dang HX, Zhao SG, Lloyd P, Aggarwal R, Alumkal JJ, et al. Genomic Hallmarks and Structural Variation in Metastatic Prostate Cancer. Cell 2018;174(3):758–69 e9 doi 10.1016/j.cell.2018.06.039. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R37] 37.Chen WS, Aggarwal R, Zhang L, Zhao SG, Thomas GV, Beer TM, et al. Genomic Drivers of Poor Prognosis and Enzalutamide Resistance in Metastatic Castration-resistant Prostate Cancer. Eur Urol 2019;76(5):562–71 doi 10.1016/j.eururo.2019.03.020. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R38] 38.Mateo J, Seed G, Bertan C, Rescigno P, Dolling D, Figueiredo I, et al. Genomics of lethal prostate cancer at diagnosis and castration resistance. J Clin Invest 2020. doi 10.1172/JCI132031. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R39] 39.Hieronymus H, Murali R, Tin A, Yadav K, Abida W, Moller H, et al. Tumor copy number alteration burden is a pan-cancer prognostic factor associated with recurrence and death. Elife 2018;7 doi 10.7554/eLife.37294. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R40] 40.Stopsack KH, Whittaker CA, Gerke TA, Loda M, Kantoff PW, Mucci LA, et al. Aneuploidy drives lethal progression in prostate cancer. Proc Natl Acad Sci U S A 2019;116(23):11390–5 doi 10.1073/pnas.1902645116. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R41] 41.Domingo-Domenech J, Vidal SJ, Rodriguez-Bravo V, Castillo-Martin M, Quinn SA, Rodriguez-Barrueco R, et al. Suppression of acquired docetaxel resistance in prostate cancer through depletion of notch- and hedgehog-dependent tumor-initiating cells. Cancer Cell 2012;22(3):373–88 doi 10.1016/j.ccr.2012.07.016. [DOI] [PMC free article] [PubMed] [Google Scholar]

[R42] 42.Wang L, Dehm SM, Hillman DW, Sicotte H, Tan W, Gormley M, et al. A prospective genome-wide study of prostate cancer metastases reveals association of wnt pathway activation and increased cell cycle proliferation with primary resistance to abiraterone acetate-prednisone. Ann Oncol 2018;29(2):352–60 doi 10.1093/annonc/mdx689. [DOI] [PMC free article] [PubMed] [Google Scholar]

PERMALINK

Oncogenic genomic alterations, clinical phenotypes, and outcomes in metastatic castration-sensitive prostate cancer

Konrad H Stopsack

Subhiksha Nandakumar

Andreas G Wibmer

Samuel Haywood

Emily S Weg

Ethan S Barnett

Chloe J Kim

Emily A Carbone

Samantha E Vasselman

Bastien Nguyen

Melanie A Hullings

Howard I Scher

Michael J Morris

David B Solit

Nikolaus Schultz

Philip W Kantoff

Wassim Abida

Abstract

Background:

Methods:

Results:

Conclusion:

Introduction

Methods

Patient population and clinical characteristics

Genomic profiling

Analysis

Results

Study population

Table 1. Patient and sample characteristics, by disease volume at genomic profiling and by timing of metastases.

Clinical phenotypes and prognosis

Figure 1.

Genomics and clinical phenotypes

Figure 2.

Figure 3.

Genomic alterations and prognosis

Figure 4.

Discussion

Data availability

Supplementary Material

Translational Relevance.

Funding:

Footnotes

References

Associated Data

Supplementary Materials

Data Availability Statement

ACTIONS

PERMALINK

RESOURCES

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Cited by other articles

Links to NCBI Databases