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1. UCHL1 is a potential molecular indicator and therapeutic target for neuroendocrine carcinomas.

Author

Liu, Shiqin, Chai, Timothy, Garcia-Marques, Fernando, Yin, Qingqing, Hsu, En-Chi, Shen, Michelle, Shaw Toland, Angus, Bermudez, Abel, Hartono, Alifiani, Massey, Christopher, Lee, Chung, Zheng, Liwei, Baron, Maya, Denning, Caden, Aslan, Merve, Nguyen, Holly, Zoubeidi, Amina, Das, Millie, Kunder, Christian, Howitt, Brooke, Soh, H, Weissman, Irving, Liss, Michael, Chin, Arnold, Brooks, James, Corey, Eva, Pitteri, Sharon, Huang, Jiaoti, Nolley, Rosie, and Stoyanova, Tanya

Subjects
UCHL1, neuroblastoma, neuroendocrine carcinomas, neuroendocrine prostate cancer, nuclear pore complex, small cell lung cancer, Male, Humans, Ubiquitin Thiolesterase, Carcinoma, Neuroendocrine, Small Cell Lung Carcinoma, Lung Neoplasms, Membrane Glycoproteins
Abstract

Neuroendocrine carcinomas, such as neuroendocrine prostate cancer and small-cell lung cancer, commonly have a poor prognosis and limited therapeutic options. We report that ubiquitin carboxy-terminal hydrolase L1 (UCHL1), a deubiquitinating enzyme, is elevated in tissues and plasma from patients with neuroendocrine carcinomas. Loss of UCHL1 decreases tumor growth and inhibits metastasis of these malignancies. UCHL1 maintains neuroendocrine differentiation and promotes cancer progression by regulating nucleoporin, POM121, and p53. UCHL1 binds, deubiquitinates, and stabilizes POM121 to regulate POM121-associated nuclear transport of E2F1 and c-MYC. Treatment with the UCHL1 inhibitor LDN-57444 slows tumor growth and metastasis across neuroendocrine carcinomas. The combination of UCHL1 inhibitors with cisplatin, the standard of care used for neuroendocrine carcinomas, significantly delays tumor growth in pre-clinical settings. Our study reveals mechanisms of UCHL1 function in regulating the progression of neuroendocrine carcinomas and identifies UCHL1 as a therapeutic target and potential molecular indicator for diagnosing and monitoring treatment responses in these malignancies.

Published
2024

3. The 5-Hydroxymethylcytosine Landscape of Prostate Cancer

Author

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

Subjects
Biological Sciences, Biomedical and Clinical Sciences, Genetics, Clinical Sciences, Oncology and Carcinogenesis, Urologic Diseases, Cancer, Prostate Cancer, Human Genome, Aging, Cancer Genomics, 4.1 Discovery and preclinical testing of markers and technologies, 2.1 Biological and endogenous factors, 4.2 Evaluation of markers and technologies, Good Health and Well Being, Male, Humans, 5-Methylcytosine, Prostatic Neoplasms, Prostate, Biopsy, Oncology & Carcinogenesis, Biochemistry and cell biology, Oncology and carcinogenesis
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.SignificanceIn 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

4. Drug-Induced Epigenomic Plasticity Reprograms Circadian Rhythm Regulation to Drive Prostate Cancer toward Androgen Independence.

Author

Linder, Simon, Hoogstraat, Marlous, Stelloo, Suzan, Eickhoff, Nils, Schuurman, Karianne, de Barros, Hilda, Alkemade, Maartje, Bekers, Elise M, Severson, Tesa M, Sanders, Joyce, Huang, Chia-Chi Flora, Morova, Tunc, Altintas, Umut Berkay, Hoekman, Liesbeth, Kim, Yongsoo, Baca, Sylvan C, Sjöström, Martin, Zaalberg, Anniek, Hintzen, Dorine C, de Jong, Jeroen, Kluin, Roelof JC, de Rink, Iris, Giambartolomei, Claudia, Seo, Ji-Heui, Pasaniuc, Bogdan, Altelaar, Maarten, Medema, René H, Feng, Felix Y, Zoubeidi, Amina, Freedman, Matthew L, Wessels, Lodewyk FA, Butler, Lisa M, Lack, Nathan A, van der Poel, Henk, Bergman, Andries M, and Zwart, Wilbert

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Prostate Cancer, Aging, Urologic Diseases, Biotechnology, Cancer, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, 2.1 Biological and endogenous factors, Aetiology, ARNTL Transcription Factors, Androgens, Cell Line, Tumor, Circadian Rhythm, Drug Resistance, Neoplasm, Epigenomics, Humans, Male, Nitriles, Prostatic Neoplasms, Castration-Resistant, Receptors, Androgen, Biochemistry and cell biology, Oncology and carcinogenesis
Abstract

In prostate cancer, androgen receptor (AR)-targeting agents are very effective in various disease stages. However, therapy resistance inevitably occurs, and little is known about how tumor cells adapt to bypass AR suppression. Here, we performed integrative multiomics analyses on tissues isolated before and after 3 months of AR-targeting enzalutamide monotherapy from patients with high-risk prostate cancer enrolled in a neoadjuvant clinical trial. Transcriptomic analyses demonstrated that AR inhibition drove tumors toward a neuroendocrine-like disease state. Additionally, epigenomic profiling revealed massive enzalutamide-induced reprogramming of pioneer factor FOXA1 from inactive chromatin sites toward active cis-regulatory elements that dictate prosurvival signals. Notably, treatment-induced FOXA1 sites were enriched for the circadian clock component ARNTL. Posttreatment ARNTL levels were associated with patients' clinical outcomes, and ARNTL knockout strongly decreased prostate cancer cell growth. Our data highlight a remarkable cistromic plasticity of FOXA1 following AR-targeted therapy and revealed an acquired dependency on the circadian regulator ARNTL, a novel candidate therapeutic target.SignificanceUnderstanding how prostate cancers adapt to AR-targeted interventions is critical for identifying novel drug targets to improve the clinical management of treatment-resistant disease. Our study revealed an enzalutamide-induced epigenomic plasticity toward prosurvival signaling and uncovered the circadian regulator ARNTL as an acquired vulnerability after AR inhibition, presenting a novel lead for therapeutic development. See related commentary by Zhang et al., p. 2017. This article is highlighted in the In This Issue feature, p. 2007.

Published
2022

5. An androgen receptor switch underlies lineage infidelity in treatment-resistant prostate cancer

Author

Davies, Alastair, Nouruzi, Shaghayegh, Ganguli, Dwaipayan, Namekawa, Takeshi, Thaper, Daksh, Linder, Simon, Karaoğlanoğlu, Fatih, Omur, Meltem E, Kim, Soojin, Kobelev, Maxim, Kumar, Sahil, Sivak, Olena, Bostock, Chiara, Bishop, Jennifer, Hoogstraat, Marlous, Talal, Amina, Stelloo, Suzan, van der Poel, Henk, Bergman, Andries M, Ahmed, Musaddeque, Fazli, Ladan, Huang, Haojie, Tilley, Wayne, Goodrich, David, Feng, Felix Y, Gleave, Martin, He, Housheng Hansen, Hach, Faraz, Zwart, Wilbert, Beltran, Himisha, Selth, Luke, and Zoubeidi, Amina

Subjects
Prostate Cancer, Genetics, Cancer, Stem Cell Research, Urologic Diseases, Aetiology, 1.1 Normal biological development and functioning, Underpinning research, 2.1 Biological and endogenous factors, Cell Line, Tumor, Enhancer of Zeste Homolog 2 Protein, Gene Expression Regulation, Neoplastic, Gene Regulatory Networks, Humans, Male, Prostatic Neoplasms, Receptors, Androgen, Signal Transduction, Biological Sciences, Medical and Health Sciences, Developmental Biology
Abstract

Cancers adapt to increasingly potent targeted therapies by reprogramming their phenotype. Here we investigated such a phenomenon in prostate cancer, in which tumours can escape epithelial lineage confinement and transition to a high-plasticity state as an adaptive response to potent androgen receptor (AR) antagonism. We found that AR activity can be maintained as tumours adopt alternative lineage identities, with changes in chromatin architecture guiding AR transcriptional rerouting. The epigenetic regulator enhancer of zeste homologue 2 (EZH2) co-occupies the reprogrammed AR cistrome to transcriptionally modulate stem cell and neuronal gene networks-granting privileges associated with both fates. This function of EZH2 was associated with T350 phosphorylation and establishment of a non-canonical polycomb subcomplex. Our study provides mechanistic insights into the plasticity of the lineage-infidelity state governed by AR reprogramming that enabled us to redirect cell fate by modulating EZH2 and AR, highlighting the clinical potential of reversing resistance phenotypes.

Published
2021

6. MYC is a regulator of androgen receptor inhibition-induced metabolic requirements in prostate cancer

Author

Crowell, Preston D., Giafaglione, Jenna M., Jones, Anthony E., Nunley, Nicholas M., Hashimoto, Takao, Delcourt, Amelie M.L., Petcherski, Anton, Agrawal, Raag, Bernard, Matthew J., Diaz, Johnny A., Heering, Kylie Y., Huang, Rong Rong, Low, Jin-Yih, Matulionis, Nedas, Navone, Nora M., Ye, Huihui, Zoubeidi, Amina, Christofk, Heather R., Rettig, Matthew B., Reiter, Robert E., Haffner, Michael C., Boutros, Paul C., Shirihai, Orian S., Divakaruni, Ajit S., and Goldstein, Andrew S.

Published
2023
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7. Reprogramming of the FOXA1 cistrome in treatment-emergent neuroendocrine prostate cancer.

Author

Baca, Sylvan C, Takeda, David Y, Seo, Ji-Heui, Hwang, Justin, Ku, Sheng Yu, Arafeh, Rand, Arnoff, Taylor, Agarwal, Supreet, Bell, Connor, O'Connor, Edward, Qiu, Xintao, Alaiwi, Sarah Abou, Corona, Rosario I, Fonseca, Marcos AS, Giambartolomei, Claudia, Cejas, Paloma, Lim, Klothilda, He, Monica, Sheahan, Anjali, Nassar, Amin, Berchuck, Jacob E, Brown, Lisha, Nguyen, Holly M, Coleman, Ilsa M, Kaipainen, Arja, De Sarkar, Navonil, Nelson, Peter S, Morrissey, Colm, Korthauer, Keegan, Pomerantz, Mark M, Ellis, Leigh, Pasaniuc, Bogdan, Lawrenson, Kate, Kelly, Kathleen, Zoubeidi, Amina, Hahn, William C, Beltran, Himisha, Long, Henry W, Brown, Myles, Corey, Eva, and Freedman, Matthew L

Subjects
Cell Line, Tumor, Animals, Humans, Neuroendocrine Tumors, Adenocarcinoma, Prostatic Neoplasms, Disease Progression, Receptors, Androgen, Gene Expression Regulation, Neoplastic, RNA Interference, Mutation, Male, Hepatocyte Nuclear Factor 3-alpha, Epigenomics, Cell Line, Tumor, Receptors, Androgen, Gene Expression Regulation, Neoplastic
Abstract

Lineage plasticity, the ability of a cell to alter its identity, is an increasingly common mechanism of adaptive resistance to targeted therapy in cancer. An archetypal example is the development of neuroendocrine prostate cancer (NEPC) after treatment of prostate adenocarcinoma (PRAD) with inhibitors of androgen signaling. NEPC is an aggressive variant of prostate cancer that aberrantly expresses genes characteristic of neuroendocrine (NE) tissues and no longer depends on androgens. Here, we investigate the epigenomic basis of this resistance mechanism by profiling histone modifications in NEPC and PRAD patient-derived xenografts (PDXs) using chromatin immunoprecipitation and sequencing (ChIP-seq). We identify a vast network of cis-regulatory elements (N~15,000) that are recurrently activated in NEPC. The FOXA1 transcription factor (TF), which pioneers androgen receptor (AR) chromatin binding in the prostate epithelium, is reprogrammed to NE-specific regulatory elements in NEPC. Despite loss of dependence upon AR, NEPC maintains FOXA1 expression and requires FOXA1 for proliferation and expression of NE lineage-defining genes. Ectopic expression of the NE lineage TFs ASCL1 and NKX2-1 in PRAD cells reprograms FOXA1 to bind to NE regulatory elements and induces enhancer activity as evidenced by histone modifications at these sites. Our data establish the importance of FOXA1 in NEPC and provide a principled approach to identifying cancer dependencies through epigenomic profiling.

Published
2021

8. CRISPRi screens reveal a DNA methylation-mediated 3D genome dependent causal mechanism in prostate cancer.

Author

Ahmed, Musaddeque, Soares, Fraser, Xia, Ji-Han, Yang, Yue, Li, Jing, Guo, Haiyang, Su, Peiran, Tian, Yijun, Lee, Hyung Joo, Wang, Miranda, Akhtar, Nayeema, Houlahan, Kathleen E, Bosch, Almudena, Zhou, Stanley, Mazrooei, Parisa, Hua, Junjie T, Chen, Sujun, Petricca, Jessica, Zeng, Yong, Davies, Alastair, Fraser, Michael, Quigley, David A, Feng, Felix Y, Boutros, Paul C, Lupien, Mathieu, Zoubeidi, Amina, Wang, Liang, Walsh, Martin J, Wang, Ting, Ren, Shancheng, Wei, Gong-Hong, and He, Housheng Hansen

Subjects
Cell Line, Tumor, Animals, Mice, Inbred NOD, Humans, Mice, SCID, Prostatic Neoplasms, Genetic Predisposition to Disease, Proto-Oncogene Proteins c-myc, Risk Factors, DNA Methylation, Polymorphism, Single Nucleotide, Quantitative Trait Loci, Male, Regulatory Elements, Transcriptional, Promoter Regions, Genetic, Genome-Wide Association Study, Carcinogenesis, CRISPR-Cas Systems, Gene Editing, CCCTC-Binding Factor, Human Genome, Aging, Prostate Cancer, Urologic Diseases, Cancer, Genetics, 2.1 Biological and endogenous factors
Abstract

Prostate cancer (PCa) risk-associated SNPs are enriched in noncoding cis-regulatory elements (rCREs), yet their modi operandi and clinical impact remain elusive. Here, we perform CRISPRi screens of 260 rCREs in PCa cell lines. We find that rCREs harboring high risk SNPs are more essential for cell proliferation and H3K27ac occupancy is a strong indicator of essentiality. We also show that cell-line-specific essential rCREs are enriched in the 8q24.21 region, with the rs11986220-containing rCRE regulating MYC and PVT1 expression, cell proliferation and tumorigenesis in a cell-line-specific manner, depending on DNA methylation-orchestrated occupancy of a CTCF binding site in between this rCRE and the MYC promoter. We demonstrate that CTCF deposition at this site as measured by DNA methylation level is highly variable in prostate specimens, and observe the MYC eQTL in the 8q24.21 locus in individuals with low CTCF binding. Together our findings highlight a causal mechanism synergistically driven by a risk SNP and DNA methylation-mediated 3D genome architecture, advocating for the integration of genetics and epigenetics in assessing risks conferred by genetic predispositions.

Published
2021

9. Celebrating the 80th anniversary of hormone ablation for prostate cancer.

Author

Zoubeidi, Amina and Ghosh, Paramita M

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Urologic Diseases, Cancer, Aging, Prostate Cancer, 6.1 Pharmaceuticals, Aetiology, 2.1 Biological and endogenous factors, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, Evaluation of treatments and therapeutic interventions, Androgen Antagonists, Androgen Receptor Antagonists, Androgens, Animals, Anniversaries and Special Events, Humans, Male, Prostatic Neoplasms, Receptors, Androgen, prostate, androgen, androgen receptor, endocrine therapy, Biological Sciences, Medical and Health Sciences, Oncology & Carcinogenesis, Clinical sciences, Oncology and carcinogenesis
Abstract

In this issue of Endocrine-Related Cancer, we are celebrating the 80th anniversary of hormone ablation as treatment for metastatic prostate cancer. Our understanding has evolved from the observation that androgen withdrawal, either surgical or pharmacological, resulted in prostatic atrophy in animal models, to its application in patients, to investigation of the mysterious way in which prostate cancer escapes androgen dependence. We are now in an era of novel AR pathway inhibitors, the combination of androgen ablation with chemotherapy, PARP inhibitors, immunotherapies, guided radiotherapy, and novel drug application based upon genetic testing of individual tumors. In this special issue, we bring together a collection of eight reviews that cover not only the history of 80 years of progress after the initial identification of androgen ablation as an effective treatment of prostate cancer, but subsequent improvements in the understanding of the biology of the disease, development of novel treatment paradigms, resistance to those treatments and disease progression following that resistance.

Published
2021

11. The DNA methylation landscape of advanced prostate cancer

Author

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

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

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

Published
2020

12. Trop2 is a driver of metastatic prostate cancer with neuroendocrine phenotype via PARP1

Author

Hsu, En-Chi, Rice, Meghan A, Bermudez, Abel, Marques, Fernando Jose Garcia, Aslan, Merve, Liu, Shiqin, Ghoochani, Ali, Zhang, Chiyuan Amy, Chen, Yun-Sheng, Zlitni, Aimen, Kumar, Sahil, Nolley, Rosalie, Habte, Frezghi, Shen, Michelle, Koul, Kashyap, Peehl, Donna M, Zoubeidi, Amina, Gambhir, Sanjiv S, Kunder, Christian A, Pitteri, Sharon J, Brooks, James D, and Stoyanova, Tanya

Subjects
Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Urologic Diseases, Aging, Prostate Cancer, Cancer, Development of treatments and therapeutic interventions, 5.1 Pharmaceuticals, Animals, Antigens, Neoplasm, Apoptosis, Biomarkers, Tumor, Bone Neoplasms, Carcinoma, Neuroendocrine, Cell Adhesion Molecules, Cell Movement, Cell Proliferation, Follow-Up Studies, Gene Expression Regulation, Neoplastic, Humans, Male, Mice, Mice, Inbred NOD, Mice, SCID, Neoplasm Invasiveness, Phenotype, Poly (ADP-Ribose) Polymerase-1, Poly(ADP-ribose) Polymerase Inhibitors, Prognosis, Prostatic Neoplasms, Castration-Resistant, Survival Rate, Tumor Cells, Cultured, Xenograft Model Antitumor Assays, prostate, cancer, NEPC, Trop2
Abstract

Resistance to androgen deprivation therapy, or castration-resistant prostate cancer (CRPC), is often accompanied by metastasis and is currently the ultimate cause of prostate cancer-associated deaths in men. Recently, secondary hormonal therapies have led to an increase of neuroendocrine prostate cancer (NEPC), a highly aggressive variant of CRPC. Here, we identify that high levels of cell surface receptor Trop2 are predictive of recurrence of localized prostate cancer. Moreover, Trop2 is significantly elevated in CRPC and NEPC, drives prostate cancer growth, and induces neuroendocrine phenotype. Overexpression of Trop2 induces tumor growth and metastasis while loss of Trop2 suppresses these abilities in vivo. Trop2-driven NEPC displays a significant up-regulation of PARP1, and PARP inhibitors significantly delay tumor growth and metastatic colonization and reverse neuroendocrine features in Trop2-driven NEPC. Our findings establish Trop2 as a driver and therapeutic target for metastatic prostate cancer with neuroendocrine phenotype and suggest that high Trop2 levels could identify cancers that are sensitive to Trop2-targeting therapies and PARP1 inhibition.

Published
2020

13. ONECUT2 is a driver of neuroendocrine prostate cancer.

Author

Guo, Haiyang, Ci, Xinpei, Ahmed, Musaddeque, Hua, Junjie Tony, Soares, Fraser, Lin, Dong, Puca, Loredana, Vosoughi, Aram, Xue, Hui, Li, Estelle, Su, Peiran, Chen, Sujun, Nguyen, Tran, Liang, Yi, Zhang, Yuzhe, Xu, Xin, Xu, Jing, Sheahan, Anjali V, Ba-Alawi, Wail, Zhang, Si, Mahamud, Osman, Vellanki, Ravi N, Gleave, Martin, Bristow, Robert G, Haibe-Kains, Benjamin, Poirier, John T, Rudin, Charles M, Tsao, Ming-Sound, Wouters, Bradly G, Fazli, Ladan, Feng, Felix Y, Ellis, Leigh, van der Kwast, Theo, Berlin, Alejandro, Koritzinsky, Marianne, Boutros, Paul C, Zoubeidi, Amina, Beltran, Himisha, Wang, Yuzhuo, and He, Housheng Hansen

Subjects
Prostate, Cell Line, Tumor, Animals, Mice, Inbred NOD, Humans, Mice, Mice, SCID, Neuroendocrine Tumors, Prostatic Neoplasms, Disease Progression, Phosphoramide Mustards, Nitroimidazoles, Homeodomain Proteins, Transcription Factors, RNA, Small Interfering, Xenograft Model Antitumor Assays, Gene Expression Profiling, Signal Transduction, Cell Proliferation, Cell Hypoxia, Gene Expression Regulation, Neoplastic, Up-Regulation, Male, Hypoxia-Inducible Factor 1, alpha Subunit, Smad3 Protein, Carcinogenesis, Datasets as Topic, Urologic Diseases, Cancer, Prostate Cancer, Aging, 2.1 Biological and endogenous factors, Cell Line, Tumor, Inbred NOD, SCID, RNA, Small Interfering, Gene Expression Regulation, Neoplastic, Hypoxia-Inducible Factor 1, alpha Subunit
Abstract

Neuroendocrine prostate cancer (NEPC), a lethal form of the disease, is characterized by loss of androgen receptor (AR) signaling during neuroendocrine transdifferentiation, which results in resistance to AR-targeted therapy. Clinically, genomically and epigenetically, NEPC resembles other types of poorly differentiated neuroendocrine tumors (NETs). Through pan-NET analyses, we identified ONECUT2 as a candidate master transcriptional regulator of poorly differentiated NETs. ONECUT2 ectopic expression in prostate adenocarcinoma synergizes with hypoxia to suppress androgen signaling and induce neuroendocrine plasticity. ONEUCT2 drives tumor aggressiveness in NEPC, partially through regulating hypoxia signaling and tumor hypoxia. Specifically, ONECUT2 activates SMAD3, which regulates hypoxia signaling through modulating HIF1α chromatin-binding, leading NEPC to exhibit higher degrees of hypoxia compared to prostate adenocarcinomas. Treatment with hypoxia-activated prodrug TH-302 potently reduces NEPC tumor growth. Collectively, these results highlight the synergy between ONECUT2 and hypoxia in driving NEPC, and emphasize the potential of hypoxia-directed therapy for NEPC patients.

Published
2019

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

Author

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

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

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

Published
2018

16. Role of Androgen Receptor Variants in Prostate Cancer: Report from the 2017 Mission Androgen Receptor Variants Meeting.

Author

Luo, Jun, Attard, Gerhardt, Balk, Steven, Bevan, Charlotte, Burnstein, Kerry, Cato, Laura, Cherkasov, Artem, De Bono, Johann, Dong, Yan, Gao, Allen, Gleave, Martin, Heemers, Hannelore, Kanayama, Mayuko, Kittler, Ralf, Lang, Joshua, Lee, Richard, Logothetis, Christopher, Matusik, Robert, Plymate, Stephen, Sawyers, Charles, Selth, Luke, Soule, Howard, Tilley, Wayne, Weigel, Nancy, Zoubeidi, Amina, Dehm, Scott, and Raj, Ganesh

Subjects
Abiraterone, Androgen receptor variant 7, Androgen receptor variants, Castration-resistant prostate cancer, Enzalutamide, Aged, Androgen Antagonists, Androstenes, Benzamides, Biomarkers, Tumor, Congresses as Topic, Disease-Free Survival, Follow-Up Studies, Humans, Male, Middle Aged, Nitriles, Phenylthiohydantoin, Prostatic Neoplasms, Castration-Resistant, Receptors, Androgen, Risk Assessment, Survival Analysis, Treatment Outcome
Abstract

CONTEXT: Although a number of studies have demonstrated the importance of constitutively active androgen receptor variants (AR-Vs) in prostate cancer, questions still remain about the precise role of AR-Vs in the progression of castration-resistant prostate cancer (CRPC). OBJECTIVE: Key stakeholders and opinion leaders in prostate cancer convened on May 11, 2017 in Boston to establish the current state of the field of AR-Vs. EVIDENCE ACQUISITION: The meeting Mission Androgen Receptor Variants was the second of its kind sponsored by the Prostate Cancer Foundation (PCF). This invitation-only event was attended by international leaders in the field and representatives from sponsoring organizations (PCF and industry sponsors). Eighteen faculty members gave short presentations, which were followed by in-depth discussions. Discussions focused on three thematic topics: (1) potential of AR-Vs as biomarkers of therapeutic resistance; (2) role of AR-Vs as functionally active CRPC progression drivers; and (3) utility of AR-Vs as therapeutic targets in CRPC. EVIDENCE SYNTHESIS: The three meeting organizers synthesized this meeting report, which is intended to summarize major data discussed at the meeting and identify key questions as well as strategies for addressing these questions. There was a critical consensus that further study of the AR-Vs is an important research focus in CRPC. Contrasting views and emphasis, each supported by data, were presented at the meeting, discussed among the participants, and synthesized in this report. CONCLUSIONS: This article highlights the state of knowledge and outlines the most pressing questions that need to be addressed to advance the AR-V field. PATIENT SUMMARY: Although further investigation is needed to delineate the role of androgen receptor (AR) variants in metastatic castration-resistant prostate cancer, advances in measurement science have enabled development of blood-based tests for treatment selection. Detection of AR variants (eg, AR-V7) identified a patient population with poor outcomes to existing AR-targeting therapies, highlighting the need for novel therapeutic agents currently under development.

Published
2018

18. Supplementary Figure 2 from Prostate Cancer Progression Relies on the Mitotic Kinase Citron Kinase

Author

Rawat, Chitra, primary, Ben-Salem, Salma, primary, Singh, Nidhi, primary, Chauhan, Gaurav, primary, Rabljenovic, Anja, primary, Vaghela, Vishwa, primary, Venkadakrishnan, Varadha Balaji, primary, Macdonald, Jonathan D., primary, Dahiya, Ujjwal R., primary, Ghanem, Yara, primary, Bachour, Salam, primary, Su, Yixue, primary, DePriest, Adam D., primary, Lee, Sanghee, primary, Muldong, Michelle, primary, Kim, Hyun-Tae, primary, Kumari, Sangeeta, primary, Valenzuela, Malyn May, primary, Zhang, Dingxiao, primary, Hu, Qiang, primary, Cortes Gomez, Eduardo, primary, Dehm, Scott M., primary, Zoubeidi, Amina, primary, Jamieson, Christina A.M., primary, Nicolas, Marlo, primary, McKenney, Jesse, primary, Willard, Belinda, primary, Klein, Eric A., primary, Magi-Galluzzi, Cristina, primary, Stauffer, Shaun R., primary, Liu, Song, primary, and Heemers, Hannelore V., primary

Published
2023
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19. Supplementary Figure 7 from Prostate Cancer Progression Relies on the Mitotic Kinase Citron Kinase

Author

Rawat, Chitra, primary, Ben-Salem, Salma, primary, Singh, Nidhi, primary, Chauhan, Gaurav, primary, Rabljenovic, Anja, primary, Vaghela, Vishwa, primary, Venkadakrishnan, Varadha Balaji, primary, Macdonald, Jonathan D., primary, Dahiya, Ujjwal R., primary, Ghanem, Yara, primary, Bachour, Salam, primary, Su, Yixue, primary, DePriest, Adam D., primary, Lee, Sanghee, primary, Muldong, Michelle, primary, Kim, Hyun-Tae, primary, Kumari, Sangeeta, primary, Valenzuela, Malyn May, primary, Zhang, Dingxiao, primary, Hu, Qiang, primary, Cortes Gomez, Eduardo, primary, Dehm, Scott M., primary, Zoubeidi, Amina, primary, Jamieson, Christina A.M., primary, Nicolas, Marlo, primary, McKenney, Jesse, primary, Willard, Belinda, primary, Klein, Eric A., primary, Magi-Galluzzi, Cristina, primary, Stauffer, Shaun R., primary, Liu, Song, primary, and Heemers, Hannelore V., primary

Published
2023
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20. Supplementary Figure 4 from Prostate Cancer Progression Relies on the Mitotic Kinase Citron Kinase

Author

Rawat, Chitra, primary, Ben-Salem, Salma, primary, Singh, Nidhi, primary, Chauhan, Gaurav, primary, Rabljenovic, Anja, primary, Vaghela, Vishwa, primary, Venkadakrishnan, Varadha Balaji, primary, Macdonald, Jonathan D., primary, Dahiya, Ujjwal R., primary, Ghanem, Yara, primary, Bachour, Salam, primary, Su, Yixue, primary, DePriest, Adam D., primary, Lee, Sanghee, primary, Muldong, Michelle, primary, Kim, Hyun-Tae, primary, Kumari, Sangeeta, primary, Valenzuela, Malyn May, primary, Zhang, Dingxiao, primary, Hu, Qiang, primary, Cortes Gomez, Eduardo, primary, Dehm, Scott M., primary, Zoubeidi, Amina, primary, Jamieson, Christina A.M., primary, Nicolas, Marlo, primary, McKenney, Jesse, primary, Willard, Belinda, primary, Klein, Eric A., primary, Magi-Galluzzi, Cristina, primary, Stauffer, Shaun R., primary, Liu, Song, primary, and Heemers, Hannelore V., primary

Published
2023
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21. Supplementary Figure 5 from Prostate Cancer Progression Relies on the Mitotic Kinase Citron Kinase

Author

Rawat, Chitra, primary, Ben-Salem, Salma, primary, Singh, Nidhi, primary, Chauhan, Gaurav, primary, Rabljenovic, Anja, primary, Vaghela, Vishwa, primary, Venkadakrishnan, Varadha Balaji, primary, Macdonald, Jonathan D., primary, Dahiya, Ujjwal R., primary, Ghanem, Yara, primary, Bachour, Salam, primary, Su, Yixue, primary, DePriest, Adam D., primary, Lee, Sanghee, primary, Muldong, Michelle, primary, Kim, Hyun-Tae, primary, Kumari, Sangeeta, primary, Valenzuela, Malyn May, primary, Zhang, Dingxiao, primary, Hu, Qiang, primary, Cortes Gomez, Eduardo, primary, Dehm, Scott M., primary, Zoubeidi, Amina, primary, Jamieson, Christina A.M., primary, Nicolas, Marlo, primary, McKenney, Jesse, primary, Willard, Belinda, primary, Klein, Eric A., primary, Magi-Galluzzi, Cristina, primary, Stauffer, Shaun R., primary, Liu, Song, primary, and Heemers, Hannelore V., primary

Published
2023
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22. Supplementary Figure 3 from Prostate Cancer Progression Relies on the Mitotic Kinase Citron Kinase

Author

Rawat, Chitra, primary, Ben-Salem, Salma, primary, Singh, Nidhi, primary, Chauhan, Gaurav, primary, Rabljenovic, Anja, primary, Vaghela, Vishwa, primary, Venkadakrishnan, Varadha Balaji, primary, Macdonald, Jonathan D., primary, Dahiya, Ujjwal R., primary, Ghanem, Yara, primary, Bachour, Salam, primary, Su, Yixue, primary, DePriest, Adam D., primary, Lee, Sanghee, primary, Muldong, Michelle, primary, Kim, Hyun-Tae, primary, Kumari, Sangeeta, primary, Valenzuela, Malyn May, primary, Zhang, Dingxiao, primary, Hu, Qiang, primary, Cortes Gomez, Eduardo, primary, Dehm, Scott M., primary, Zoubeidi, Amina, primary, Jamieson, Christina A.M., primary, Nicolas, Marlo, primary, McKenney, Jesse, primary, Willard, Belinda, primary, Klein, Eric A., primary, Magi-Galluzzi, Cristina, primary, Stauffer, Shaun R., primary, Liu, Song, primary, and Heemers, Hannelore V., primary

Published
2023
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23. Supplementary Figure 6 from Prostate Cancer Progression Relies on the Mitotic Kinase Citron Kinase

Author

Rawat, Chitra, primary, Ben-Salem, Salma, primary, Singh, Nidhi, primary, Chauhan, Gaurav, primary, Rabljenovic, Anja, primary, Vaghela, Vishwa, primary, Venkadakrishnan, Varadha Balaji, primary, Macdonald, Jonathan D., primary, Dahiya, Ujjwal R., primary, Ghanem, Yara, primary, Bachour, Salam, primary, Su, Yixue, primary, DePriest, Adam D., primary, Lee, Sanghee, primary, Muldong, Michelle, primary, Kim, Hyun-Tae, primary, Kumari, Sangeeta, primary, Valenzuela, Malyn May, primary, Zhang, Dingxiao, primary, Hu, Qiang, primary, Cortes Gomez, Eduardo, primary, Dehm, Scott M., primary, Zoubeidi, Amina, primary, Jamieson, Christina A.M., primary, Nicolas, Marlo, primary, McKenney, Jesse, primary, Willard, Belinda, primary, Klein, Eric A., primary, Magi-Galluzzi, Cristina, primary, Stauffer, Shaun R., primary, Liu, Song, primary, and Heemers, Hannelore V., primary

Published
2023
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24. Supplementary Figure 1 from Prostate Cancer Progression Relies on the Mitotic Kinase Citron Kinase

Author

Rawat, Chitra, primary, Ben-Salem, Salma, primary, Singh, Nidhi, primary, Chauhan, Gaurav, primary, Rabljenovic, Anja, primary, Vaghela, Vishwa, primary, Venkadakrishnan, Varadha Balaji, primary, Macdonald, Jonathan D., primary, Dahiya, Ujjwal R., primary, Ghanem, Yara, primary, Bachour, Salam, primary, Su, Yixue, primary, DePriest, Adam D., primary, Lee, Sanghee, primary, Muldong, Michelle, primary, Kim, Hyun-Tae, primary, Kumari, Sangeeta, primary, Valenzuela, Malyn May, primary, Zhang, Dingxiao, primary, Hu, Qiang, primary, Cortes Gomez, Eduardo, primary, Dehm, Scott M., primary, Zoubeidi, Amina, primary, Jamieson, Christina A.M., primary, Nicolas, Marlo, primary, McKenney, Jesse, primary, Willard, Belinda, primary, Klein, Eric A., primary, Magi-Galluzzi, Cristina, primary, Stauffer, Shaun R., primary, Liu, Song, primary, and Heemers, Hannelore V., primary

Published
2023
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25. Prostate Cancer Progression Relies on the Mitotic Kinase Citron Kinase

Author

Rawat, Chitra, primary, Ben-Salem, Salma, additional, Singh, Nidhi, additional, Chauhan, Gaurav, additional, Rabljenovic, Anja, additional, Vaghela, Vishwa, additional, Venkadakrishnan, Varadha Balaji, additional, Macdonald, Jonathan D., additional, Dahiya, Ujjwal R., additional, Ghanem, Yara, additional, Bachour, Salam, additional, Su, Yixue, additional, DePriest, Adam D., additional, Lee, Sanghee, additional, Muldong, Michelle, additional, Kim, Hyun-Tae, additional, Kumari, Sangeeta, additional, Valenzuela, Malyn May, additional, Zhang, Dingxiao, additional, Hu, Qiang, additional, Cortes Gomez, Eduardo, additional, Dehm, Scott M., additional, Zoubeidi, Amina, additional, Jamieson, Christina A.M., additional, Nicolas, Marlo, additional, McKenney, Jesse, additional, Willard, Belinda, additional, Klein, Eric A., additional, Magi-Galluzzi, Cristina, additional, Stauffer, Shaun R., additional, Liu, Song, additional, and Heemers, Hannelore V., additional

Published
2023
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26. Data from A Multivalent Peptoid Conjugate Modulates Androgen Receptor Transcriptional Activity to Inhibit Therapy-resistant Prostate Cancer

Author

Habault, Justine, primary, Schneider, Jeffrey A., primary, Ha, Susan, primary, Ruoff, Rachel, primary, Pereira, Luiza D., primary, Puccini, Joseph, primary, Ranieri, Michela, primary, Ayasun, Ruveyda, primary, Deng, Jiehui, primary, Kasper, Amanda C., primary, Bar-Sagi, Dafna, primary, Wong, Kwok-Kin, primary, Zoubeidi, Amina, primary, Claessens, Frank, primary, Wise, David R., primary, Logan, Susan K., primary, Kirshenbaum, Kent, primary, and Garabedian, Michael J., primary

Published
2023
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27. Supplementary Figure Legends from A Multivalent Peptoid Conjugate Modulates Androgen Receptor Transcriptional Activity to Inhibit Therapy-resistant Prostate Cancer

Author

Habault, Justine, primary, Schneider, Jeffrey A., primary, Ha, Susan, primary, Ruoff, Rachel, primary, Pereira, Luiza D., primary, Puccini, Joseph, primary, Ranieri, Michela, primary, Ayasun, Ruveyda, primary, Deng, Jiehui, primary, Kasper, Amanda C., primary, Bar-Sagi, Dafna, primary, Wong, Kwok-Kin, primary, Zoubeidi, Amina, primary, Claessens, Frank, primary, Wise, David R., primary, Logan, Susan K., primary, Kirshenbaum, Kent, primary, and Garabedian, Michael J., primary

Published
2023
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28. Figure S4 from A Multivalent Peptoid Conjugate Modulates Androgen Receptor Transcriptional Activity to Inhibit Therapy-resistant Prostate Cancer

Author

Habault, Justine, primary, Schneider, Jeffrey A., primary, Ha, Susan, primary, Ruoff, Rachel, primary, Pereira, Luiza D., primary, Puccini, Joseph, primary, Ranieri, Michela, primary, Ayasun, Ruveyda, primary, Deng, Jiehui, primary, Kasper, Amanda C., primary, Bar-Sagi, Dafna, primary, Wong, Kwok-Kin, primary, Zoubeidi, Amina, primary, Claessens, Frank, primary, Wise, David R., primary, Logan, Susan K., primary, Kirshenbaum, Kent, primary, and Garabedian, Michael J., primary

Published
2023
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29. The long noncoding RNA H19 regulates tumor plasticity in neuroendocrine prostate cancer

Author

Singh, Neha, Ramnarine, Varune R., Song, Jin H., Pandey, Ritu, Padi, Sathish K. R., Nouri, Mannan, Olive, Virginie, Kobelev, Maxim, Okumura, Koichi, McCarthy, David, Hanna, Michelle M., Mukherjee, Piali, Sun, Belinda, Lee, Benjamin R., Parker, J. Brandon, Chakravarti, Debabrata, Warfel, Noel A., Zhou, Muhan, Bearss, Jeremiah J., Gibb, Ewan A., Alshalalfa, Mohammed, Karnes, R. Jefferey, Small, Eric J., Aggarwal, Rahul, Feng, Felix, Wang, Yuzhuo, Buttyan, Ralph, Zoubeidi, Amina, Rubin, Mark, Gleave, Martin, Slack, Frank J., Davicioni, Elai, Beltran, Himisha, Collins, Colin, and Kraft, Andrew S.

Published
2021
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32. Opposing transcriptional programs of KLF5 and AR emerge during therapy for advanced prostate cancer

Author

Che, Meixia, Chaturvedi, Aashi, Munro, Sarah A., Pitzen, Samuel P., Ling, Alex, Zhang, Weijie, Mentzer, Josh, Ku, Sheng-Yu, Puca, Loredana, Zhu, Yanyun, Bergman, Andries M., Severson, Tesa M., Forster, Colleen, Liu, Yuzhen, Hildebrand, Jacob, Daniel, Mark, Wang, Ting-You, Selth, Luke A., Hickey, Theresa, Zoubeidi, Amina, Gleave, Martin, Bareja, Rohan, Sboner, Andrea, Tilley, Wayne, Carroll, Jason S., Tan, Winston, Kohli, Manish, Yang, Rendong, Hsieh, Andrew C., Murugan, Paari, Zwart, Wilbert, Beltran, Himisha, Huang, R. Stephanie, and Dehm, Scott M.

Published
2021
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33. Ivermectin inhibits HSP27 and potentiates efficacy of oncogene targeting in tumor models

Author

Nappi, Lucia, Aguda, Adeleke H., Nakouzi, Nader Al, Lelj-Garolla, Barbara, Beraldi, Eliana, Lallous, Nada, Thi, Marisa, Moore, Susan, Fazli, Ladan, Battsogt, Dulguun, Stief, Sophie, Ban, Fuqiang, Nguyen, Nham T., Saxena, Neetu, Dueva, Evgenia, Zhang, Fan, Yamazaki, Takeshi, Zoubeidi, Amina, Cherkasov, Artem, Brayer, Gary D., and Gleave, Martin

Subjects
Enzalutamide -- Analysis, Ivermectin -- Analysis, Tumors -- Genetic aspects -- Analysis, Heat shock proteins -- Analysis, Drug discovery -- Analysis, Biochemistry, Cancer, Serine, Health care industry
Abstract

HSP27 is highly expressed in, and supports oncogene addiction of, many cancers. HSP27 phosphorylation is a limiting step for activation of this protein and a target for inhibition, but its highly disordered structure challenges rational structure-guided drug discovery. We performed multistep biochemical, structural, and computational experiments to define a spherical 24-monomer complex composed of 12 HSP27 dimers with a phosphorylation pocket flanked by serine residues between their N-terminal domains. Ivermectin directly binds this pocket to inhibit MAPKAP2-mediated HSP27 phosphorylation and depolymerization, thereby blocking HSP27-regulated survival signaling and client-oncoprotein interactions. Ivermectin potentiated activity of anti-androgen receptor and anti-EGFR drugs in prostate and EGFR/HER2-driven tumor models, respectively, identifying a repurposing approach for cotargeting stress-adaptive responses to overcome resistance to inhibitors of oncogenic pathway signaling., Introduction Small heat shock proteins (sHSPs) are ATP-independent molecular chaperones characterized by a conserved [alpha]-crystallin domain located between a highly flexible, variable C-terminal region and a poorly conserved, disorganized N-terminal [...]

Published
2020
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34. Castration-Resistant Prostate Cancer

Author

Davies, Alastair H., Bishop, Jennifer L., Zoubeidi, Amina, Cagle, Philip T., Series editor, Robinson, Brian D., editor, Mosquera, Juan Miguel, editor, Ro, Jae Y., editor, and Divatia, Mukul, editor

Published
2018
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36. A multivalent peptoid conjugate modulates androgen receptor transcriptional activity to inhibit therapy-resistant prostate cancer

Author

Habault, Justine, primary, Schneider, Jeffrey A., additional, Ha, Susan, additional, Ruoff, Rachel, additional, Doro Pereira, Luiza D., additional, Puccini, Joseph, additional, Ranieri, Michela, additional, Ayasun, Ruveyda, additional, Deng, Jiehui, additional, Kasper, Amanda C., additional, Bar-Sagi, Dafna, additional, Wong, Kwok-Kin, additional, Zoubeidi, Amina, additional, Claessens, Frank, additional, Wise, David R., additional, Logan, Susan K., additional, Kirshenbaum, Kent, additional, and Garabedian, Michael J., additional

Published
2023
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40. Supplementary Figure from Drug-Induced Epigenomic Plasticity Reprograms Circadian Rhythm Regulation to Drive Prostate Cancer toward Androgen Independence

Author

Linder, Simon, primary, Hoogstraat, Marlous, primary, Stelloo, Suzan, primary, Eickhoff, Nils, primary, Schuurman, Karianne, primary, de Barros, Hilda, primary, Alkemade, Maartje, primary, Bekers, Elise M., primary, Severson, Tesa M., primary, Sanders, Joyce, primary, Huang, Chia-Chi Flora, primary, Morova, Tunc, primary, Altintas, Umut Berkay, primary, Hoekman, Liesbeth, primary, Kim, Yongsoo, primary, Baca, Sylvan C., primary, Sjöström, Martin, primary, Zaalberg, Anniek, primary, Hintzen, Dorine C., primary, de Jong, Jeroen, primary, Kluin, Roelof J.C., primary, de Rink, Iris, primary, Giambartolomei, Claudia, primary, Seo, Ji-Heui, primary, Pasaniuc, Bogdan, primary, Altelaar, Maarten, primary, Medema, René H., primary, Feng, Felix Y., primary, Zoubeidi, Amina, primary, Freedman, Matthew L., primary, Wessels, Lodewyk F.A., primary, Butler, Lisa M., primary, Lack, Nathan A., primary, van der Poel, Henk, primary, Bergman, Andries M., primary, and Zwart, Wilbert, primary

Published
2023
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42. Supplementary Data from Drug-Induced Epigenomic Plasticity Reprograms Circadian Rhythm Regulation to Drive Prostate Cancer toward Androgen Independence

Author

Linder, Simon, primary, Hoogstraat, Marlous, primary, Stelloo, Suzan, primary, Eickhoff, Nils, primary, Schuurman, Karianne, primary, de Barros, Hilda, primary, Alkemade, Maartje, primary, Bekers, Elise M., primary, Severson, Tesa M., primary, Sanders, Joyce, primary, Huang, Chia-Chi Flora, primary, Morova, Tunc, primary, Altintas, Umut Berkay, primary, Hoekman, Liesbeth, primary, Kim, Yongsoo, primary, Baca, Sylvan C., primary, Sjöström, Martin, primary, Zaalberg, Anniek, primary, Hintzen, Dorine C., primary, de Jong, Jeroen, primary, Kluin, Roelof J.C., primary, de Rink, Iris, primary, Giambartolomei, Claudia, primary, Seo, Ji-Heui, primary, Pasaniuc, Bogdan, primary, Altelaar, Maarten, primary, Medema, René H., primary, Feng, Felix Y., primary, Zoubeidi, Amina, primary, Freedman, Matthew L., primary, Wessels, Lodewyk F.A., primary, Butler, Lisa M., primary, Lack, Nathan A., primary, van der Poel, Henk, primary, Bergman, Andries M., primary, and Zwart, Wilbert, primary

Published
2023
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43. Data from Drug-Induced Epigenomic Plasticity Reprograms Circadian Rhythm Regulation to Drive Prostate Cancer toward Androgen Independence

Author

Linder, Simon, primary, Hoogstraat, Marlous, primary, Stelloo, Suzan, primary, Eickhoff, Nils, primary, Schuurman, Karianne, primary, de Barros, Hilda, primary, Alkemade, Maartje, primary, Bekers, Elise M., primary, Severson, Tesa M., primary, Sanders, Joyce, primary, Huang, Chia-Chi Flora, primary, Morova, Tunc, primary, Altintas, Umut Berkay, primary, Hoekman, Liesbeth, primary, Kim, Yongsoo, primary, Baca, Sylvan C., primary, Sjöström, Martin, primary, Zaalberg, Anniek, primary, Hintzen, Dorine C., primary, de Jong, Jeroen, primary, Kluin, Roelof J.C., primary, de Rink, Iris, primary, Giambartolomei, Claudia, primary, Seo, Ji-Heui, primary, Pasaniuc, Bogdan, primary, Altelaar, Maarten, primary, Medema, René H., primary, Feng, Felix Y., primary, Zoubeidi, Amina, primary, Freedman, Matthew L., primary, Wessels, Lodewyk F.A., primary, Butler, Lisa M., primary, Lack, Nathan A., primary, van der Poel, Henk, primary, Bergman, Andries M., primary, and Zwart, Wilbert, primary

Published
2023
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44. Abstract 3441: A multivalent peptoid conjugate that inhibits therapy-resistant prostate cancer cell proliferation by modulating androgen receptor transcriptional activity

Author

Habault, Justine, primary, Schneider, Jeffrey A., additional, Ha, Susan, additional, Ruoff, Rachel, additional, Puccini, Joseph, additional, Bar-Sagi, Dafna, additional, Wong, Kwok-Kin, additional, Zoubeidi, Amina, additional, Claessens, Frank, additional, Wise, David R., additional, Logan, Susan K., additional, Kirshenbaum, Kent, additional, and Garabedian, Michael J., additional

Published
2023
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45. Supplementary Methods and Materials from A Novel Antiandrogen, Compound 30, Suppresses Castration-Resistant and MDV3100-Resistant Prostate Cancer Growth In Vitro and In Vivo

Author

Kuruma, Hidetoshi, primary, Matsumoto, Hiroaki, primary, Shiota, Masaki, primary, Bishop, Jennifer, primary, Lamoureux, Francois, primary, Thomas, Christian, primary, Briere, David, primary, Los, Gerrit, primary, Gleave, Martin, primary, Fanjul, Andrea, primary, and Zoubeidi, Amina, primary

Published
2023
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46. Supplementary Table 1 from A Novel Antiandrogen, Compound 30, Suppresses Castration-Resistant and MDV3100-Resistant Prostate Cancer Growth In Vitro and In Vivo

Author

Kuruma, Hidetoshi, primary, Matsumoto, Hiroaki, primary, Shiota, Masaki, primary, Bishop, Jennifer, primary, Lamoureux, Francois, primary, Thomas, Christian, primary, Briere, David, primary, Los, Gerrit, primary, Gleave, Martin, primary, Fanjul, Andrea, primary, and Zoubeidi, Amina, primary

Published
2023
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48. Supplementary Figure 1 from Transcription Factor Stat5 Knockdown Enhances Androgen Receptor Degradation and Delays Castration-Resistant Prostate Cancer Progression In vivo

Author

Thomas, Christian, primary, Zoubeidi, Amina, primary, Kuruma, Hidetoshi, primary, Fazli, Ladan, primary, Lamoureux, Francois, primary, Beraldi, Eliana, primary, Monia, Brett P., primary, MacLeod, A. Robert, primary, Thüroff, Joachim W., primary, and Gleave, Martin E., primary

Published
2023
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49. Supplementary Figure 1 from A Novel Antiandrogen, Compound 30, Suppresses Castration-Resistant and MDV3100-Resistant Prostate Cancer Growth In Vitro and In Vivo

Author

Kuruma, Hidetoshi, primary, Matsumoto, Hiroaki, primary, Shiota, Masaki, primary, Bishop, Jennifer, primary, Lamoureux, Francois, primary, Thomas, Christian, primary, Briere, David, primary, Los, Gerrit, primary, Gleave, Martin, primary, Fanjul, Andrea, primary, and Zoubeidi, Amina, primary

Published
2023
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