Gene Expression Analysis of Human Prostate Carcinoma during Hormonal Therapy Identifies Androgen-Responsive Genes and Mechanisms of Therapy Resistance

Holzbeierlein, Jeff M.; Lal, Priti; Latulippe, Éva; Smith, Alex; Satagopan, Jaya M.; Zhang, Liying; Ryan, Charles J.; Smith, Steve; Scher, Howard I.; Scardino, Peter T.; Reuter, Victor E.; Gerald, William L.

doi:10.1016/s0002-9440(10)63112-4

Cited by 521 publications

(409 citation statements)

References 21 publications

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“…The second cohort consisted of patients treated for prostate cancer at MSKCC and consisted of prostatic tissues obtained from therapeutic or diagnostic procedures performed as part of routine clinical management of disease, hereafter referred to as the Holzbeierlein cohort. 26 This cohort was composed of 23 primary prostate tumor samples from men who received no therapy before surgery [eight of which had subsequent biochemical recurrence (BCR)], 17 primary prostate tumor samples from men who received 3 months androgen deprivation therapy (ADT) before surgery, and nine metastatic prostate cancer samples, 3 of which had progressed after ADT (Supporting Information Table 2). Expression profiling of the samples in this cohort was carried out using Affymetrix U95 human gene arrays.…”

Section: Public Prostate Cancer Cohortsmentioning

confidence: 99%

A gene signature identified using a mouse model of androgen receptor‐dependent prostate cancer predicts biochemical relapse in human disease

Thompson

Day

Bianco‐Miotto

et al. 2012

Intl Journal of Cancer

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Mutations in the androgen receptor (AR) have been detected in experimental and clinical prostate tumors. Mice with enforced prostate-specific expression of one such receptor variant, AR-E231G, invariably develop prostatic intraepithelial neoplasia by 12 weeks and metastatic prostate cancer by 52 weeks. The aim of this study was to identify genes with altered expression in the prostates of AR-E231G mice at an early stage of disease that may act as drivers of AR-mediated tumorigenesis. The gene expression profile of AR-E231G prostate tissue from 12-week-old mice was compared to an equivalent profile from mice expressing the AR-T857A receptor variant (analogous to the AR-T877A variant in LNCaP cells), which do not develop prostate tumors. One hundred and thirty-two genes were differentially expressed in AR-E231G prostates. Classification of these genes revealed enrichment for cellular pathways known to be involved in prostate cancer, including cell cycle and lipid metabolism. Suppression of two genes upregulated in the AR-E231G model, ADM and CITED1, increased cell death and reduced proliferation of human prostate cancer cells. Many genes differentially expressed in AR-E231G prostates are also deregulated in human tumors. Three of these genes, ID4, NR2F1 and PTGDS, which were expressed at consistently lower levels in clinical prostate cancer compared to nonmalignant tissues, formed a signature that predicted biochemical relapse (hazard ratio 2.2, p 5 0.038). We believe that our findings support the value of this novel mouse model of prostate cancer to identify candidate therapeutic targets and/or biomarkers of human disease.

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Section: Public Prostate Cancer Cohortsmentioning

confidence: 99%

A gene signature identified using a mouse model of androgen receptor‐dependent prostate cancer predicts biochemical relapse in human disease

Thompson

Day

Bianco‐Miotto

et al. 2012

Intl Journal of Cancer

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“…The androgen receptor signalling pathway is critical to the development and progression of CaP and BPH (Holzbeierlein et al, 2004). The AR mediates male sexual differentiation during development, sperm production from puberty, and maintenance of normal prostate (Heinlein and Chang, 2004).…”

Section: Androgen Receptor Signalling Pathwaymentioning

confidence: 99%

Androgen receptor signalling in prostate: Effects of stromal factors on normal and cancer stem cells

Berry

Maitland

Collins

2008

Molecular and Cellular Endocrinology

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Please cite this article as: Berry, P.A., Maitland, N.J., Collins, A.T., Androgen receptor signalling in prostate: effects of stromal factors on normal and cancer stem cells, Molecular and Cellular Endocrinology (2007), doi:10.1016/j.mce.2008 This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. AbstractThe prostate gland is the most common site for cancer in males within the developed world. Androgens play a vital role in prostate development, maintenance of tissue function and pathogenesis of prostate disease. The androgen receptor signalling pathway facilitates that role in both the epithelial compartment and in the underlying stroma. Stroma is a key mediator of androgenic effects upon the epithelium and can regulate both the fate of the epithelial stem cell and potentially the initiation and progression of prostate cancer. Different groups of growth factors are expressed by stroma, which control proliferation, and differentiation of prostate epithelium demonstrating a critical role for stroma in epithelial growth and homeostasis. Paracrine stromal proteins may offer the possibility to control tumour stem cell growth and could permit prostate-specific targeting of both therapies and of androgenresponsive proteins. The effect of 5-dihydrotestosterone, the more potent metabolite of testosterone, on expression of androgen regulated genes in stroma from benign prostatic hyperplasia is a key mediator of epithelial cell fate. Global gene expression arrays have recently identified new candidate genes in androgen responsive stroma, some of which have androgen receptor binding sites in their promoter regions. Some of these genes have direct androgen receptor binding ability.

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“…Evidence has accumulated in recent years for each of these mechanisms, suggesting that these are not mutually exclusive and that substantial hetero geneity is present [2]. It is becoming clear, for example, that ADT causes growth arrest, but does not induce significant apoptosis in prostate cancer cells [7].…”

mentioning

confidence: 99%

“…More recent in vitro evidence had shown that a subset of prostate cancer cells that survive androgendepleted conditions express increased levels of stem cell markers and are able to repopulate the tumor, possibly through adaptive AR pathway changes [9]. These adaptive changes include AR overexpression [6,10] or gain-of-function mutations [2,4] that increase receptor sensitivity to circulating androgens. Alternatively, these mutations can also allow AR to be activated by noncanonical ligands [2], such as other steroids (e.g., progesterone) [1], or even by agents initially used as antiandrogens in the same Editorial patient (e.g., flutamide and bicalutamide).…”

mentioning

confidence: 99%

Abiraterone acetate, a first-in-class CYP17 inhibitor, establishes a new treatment paradigm in castration-resistant prostate cancer

Bedoya¹,

Mitsiades²

2012

Expert Review of Anticancer Therapy

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Gene Expression Analysis of Human Prostate Carcinoma during Hormonal Therapy Identifies Androgen-Responsive Genes and Mechanisms of Therapy Resistance

Cited by 521 publications

References 21 publications

A gene signature identified using a mouse model of androgen receptor‐dependent prostate cancer predicts biochemical relapse in human disease

A gene signature identified using a mouse model of androgen receptor‐dependent prostate cancer predicts biochemical relapse in human disease

Androgen receptor signalling in prostate: Effects of stromal factors on normal and cancer stem cells

Abiraterone acetate, a first-in-class CYP17 inhibitor, establishes a new treatment paradigm in castration-resistant prostate cancer

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