Your search keyword '"Corey, Eva"' showing total 489 results

1. Functional inversion of circadian regulator REV-ERBα leads to tumorigenic gene reprogramming

Author

Yang, Yatian, Zhang, Xiong, Cai, Demin, Zheng, Xingling, Zhao, Xuan, Zou, June X, Zhang, Jin, Borowsky, Alexander D, Dall’Era, Marc A, Corey, Eva, Mitsiades, Nicholas, Kung, Hsing-Jien, Chen, Xinbin, Li, Jian Jian, Downes, Michael, Evans, Ronald M, and Chen, Hong-Wu

Subjects

Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Biological Sciences, Genetics, Cancer, Human Genome, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Nuclear Receptor Subfamily 1, Group D, Member 1, Humans, Animals, Circadian Rhythm, Carcinogenesis, Mice, Gene Expression Regulation, Neoplastic, Transcription Factors, Hepatocyte Nuclear Factor 3-alpha, Signal Transduction, Cell Line, Tumor, Neoplasms, Cell Cycle Proteins, Nuclear Receptor Co-Repressor 1, Bromodomain Containing Proteins, CRPC, REV-ERBα, antagonist, liver, prostate

Abstract

Profound functional switch of key regulatory factors may play a major role in homeostasis and disease. Dysregulation of circadian rhythm (CR) is strongly implicated in cancer with mechanisms poorly understood. We report here that the function of REV-ERBα, a major CR regulator of the orphan nuclear receptor subfamily, is dramatically altered in tumors in both its genome binding and functional mode. Loss of CR is linked to a functional inversion of REV-ERBα from a repressor in control of CR and metabolic gene programs in normal tissues to a strong activator in different cancers. Through changing its association from NCoR/HDAC3 corepressor complex to BRD4/p300 coactivators, REV-ERBα directly activates thousands of genes including tumorigenic programs such as MAPK and PI3K-Akt signaling. Functioning as a master transcriptional activator, REV-ERBα partners with pioneer factor FOXA1 and directly stimulates a large number of signaling genes, including multiple growth factors, receptor tyrosine kinases, RASs, AKTs, and MAPKs. Moreover, elevated REV-ERBα reprograms FOXA1 to bind new targets through a BRD4-mediated increase in local chromatin accessibility. Pharmacological targeting with SR8278 diminishes the function of both REV-ERBα and FOXA1 and synergizes with BRD4 inhibitor in effective suppression of tumorigenic programs and tumor growth. Thus, our study revealed a functional inversion by a CR regulator in driving gene reprogramming as an unexpected paradigm of tumorigenesis mechanism and demonstrated a high effectiveness of therapeutic targeting such switch.

Published

2024

2. Plexin D1 emerges as a novel target in the development of neural lineage plasticity in treatment-resistant prostate cancer

Author

Chen, Bo, Xu, Pengfei, Yang, Joy C, Nip, Christopher, Wang, Leyi, Shen, Yuqiu, Ning, Shu, Shang, Yufeng, Corey, Eva, Gao, Allen C, Gestwicki, Jason E, Wei, Qiang, Liu, Liangren, and Liu, Chengfei

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Prostate Cancer, Genetics, Urologic Diseases, Biotechnology, Cancer, 2.1 Biological and endogenous factors, 5.1 Pharmaceuticals, Humans, Male, Animals, Mice, Drug Resistance, Neoplasm, Cell Line, Tumor, Prostatic Neoplasms, Cell Proliferation, Gene Expression Regulation, Neoplastic, Cell Lineage, Nerve Tissue Proteins, Xenograft Model Antitumor Assays, Cell Plasticity, Receptors, Cell Surface, Prognosis, Membrane Glycoproteins, Intracellular Signaling Peptides and Proteins, Oncology & Carcinogenesis, Biochemistry and cell biology, Oncology and carcinogenesis

Abstract

Treatment-induced neuroendocrine prostate cancer (t-NEPC) often arises from adenocarcinoma via lineage plasticity in response to androgen receptor signaling inhibitors, such as enzalutamide. However, the specific regulators and targets involved in the transition to NEPC are not well understood. Plexin D1 (PLXND1) is a cellular receptor of the semaphorin (SEMA) family that plays important roles in modulating the cytoskeleton and cell adhesion. Here, we found that PLXND1 was highly expressed and positively correlated with neuroendocrine markers in patients with NEPC. High PLXND1 expression was associated with poorer prognosis in prostate cancer patients. Additionally, PLXND1 was upregulated and negatively regulated by androgen receptor signaling in enzalutamide-resistant cells. Knockdown or knockout of PLXND1 inhibited neural lineage pathways, thereby suppressing NEPC cell proliferation, patient derived xenograft (PDX) tumor organoid viability, and xenograft tumor growth. Mechanistically, the heat shock protein 70 (HSP70) regulated PLXND1 protein stability through degradation, and inhibition of HSP70 decreased PLXND1 expression and NEPC organoid growth. In summary, our findings indicate that PLXND1 could serve as a promising therapeutic target and molecular marker for NEPC.

Published

2024

3. 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

4. Stromal-derived MAOB promotes prostate cancer growth and progression.

Author

Pu, Tianjie, Wang, Jing, Wei, Jing, Zeng, Alan, Zhang, Jinglong, Chen, Jingrui, Yin, Lijuan, Li, Jingjing, Lin, Tzu-Ping, Melamed, Jonathan, Corey, Eva, Gao, Allen, and Wu, Boyang

Subjects

Male, Humans, Animals, Mice, Monoamine Oxidase, Cell Line, Tumor, Prostatic Neoplasms, Signal Transduction, Fibroblasts, Tumor Microenvironment

Abstract

Prostate cancer (PC) develops in a microenvironment where the stromal cells modulate adjacent tumor growth and progression. Here, we demonstrated elevated levels of monoamine oxidase B (MAOB), a mitochondrial enzyme that degrades biogenic and dietary monoamines, in human PC stroma, which was associated with poor clinical outcomes of PC patients. Knockdown or overexpression of MAOB in human prostate stromal fibroblasts indicated that MAOB promotes cocultured PC cell proliferation, migration, and invasion and co-inoculated prostate tumor growth in mice. Mechanistically, MAOB induces a reactive stroma with activated marker expression, increased extracellular matrix remodeling, and acquisition of a protumorigenic phenotype through enhanced production of reactive oxygen species. Moreover, MAOB transcriptionally activates CXCL12 through Twist1 synergizing with TGFβ1-dependent Smads in prostate stroma, which stimulates tumor-expressed CXCR4-Src/JNK signaling in a paracrine manner. Pharmacological inhibition of stromal MAOB restricted PC xenograft growth in mice. Collectively, these findings characterize the contribution of MAOB to PC and suggest MAOB as a potential stroma-based therapeutic target.

Published

2024

5. Proteostasis perturbation of N-Myc leveraging HSP70 mediated protein turnover improves treatment of neuroendocrine prostate cancer

Author

Xu, Pengfei, Yang, Joy C, Chen, Bo, Ning, Shu, Zhang, Xiong, Wang, Leyi, Nip, Christopher, Shen, Yuqiu, Johnson, Oleta T, Grigorean, Gabriela, Phinney, Brett, Liu, Liangren, Wei, Qiang, Corey, Eva, Tepper, Clifford G, Chen, Hong-Wu, Evans, Christopher P, Dall’Era, Marc A, Gao, Allen C, Gestwicki, Jason E, and Liu, Chengfei

Subjects

Biochemistry and Cell Biology, Biomedical and Clinical Sciences, Oncology and Carcinogenesis, Biological Sciences, Prostate Cancer, Urologic Diseases, Neurosciences, Cancer, 5.1 Pharmaceuticals, Male, Humans, Prostatic Neoplasms, HSP70 Heat-Shock Proteins, Ubiquitin-Protein Ligases, Ubiquitination, Cell Line, Tumor, Proteostasis, Animals, Aurora Kinase A, N-Myc Proto-Oncogene Protein, Mice, Carcinoma, Neuroendocrine, Neuroendocrine Tumors

Abstract

N-Myc is a key driver of neuroblastoma and neuroendocrine prostate cancer (NEPC). One potential way to circumvent the challenge of undruggable N-Myc is to target the protein homeostasis (proteostasis) system that maintains N-Myc levels. Here, we identify heat shock protein 70 (HSP70) as a top partner of N-Myc, which binds a conserved "SELILKR" motif and prevents the access of E3 ubiquitin ligase, STIP1 homology and U-box containing protein 1 (STUB1), possibly through steric hindrance. When HSP70's dwell time on N-Myc is increased by treatment with the HSP70 allosteric inhibitor, STUB1 is in close proximity with N-Myc and becomes functional to promote N-Myc ubiquitination on the K416 and K419 sites and forms polyubiquitination chains linked by the K11 and K63 sites. Notably, HSP70 inhibition significantly suppressed NEPC tumor growth, increased the efficacy of aurora kinase A (AURKA) inhibitors, and limited the expression of neuroendocrine-related pathways.

Published

2024

6. Targeting the αVβ3/NgR2 pathway in neuroendocrine prostate cancer.

Author

Testa, Anna, Quaglia, Fabio, Naranjo, Nicole, Verrillo, Cecilia, Shields, Christopher, Lin, Stephen, Pickles, Maxwell, Hamza, Drini, Von Schalscha, Tami, Leiby, Benjamin, Liu, Qin, Ding, Jianyi, Kelly, William, Hooper, D, Corey, Eva, Plow, Edward, Altieri, Dario, Languino, Lucia, and Cheresh, David

Subjects

Monocytes, Neuroendocrine prostate cancer, NgR2, Patient plasma, Small extracellular vesicles, αVβ3 integrin, Male, Humans, Prostatic Neoplasms, Androgen Antagonists, Signal Transduction, Antibodies, Monoclonal, Integrins, Integrin alphaVbeta3, Cell Line, Tumor

Abstract

Highly aggressive, metastatic, neuroendocrine prostate cancer, which typically develops from prostate cancer cells acquiring resistance to androgen deprivation therapy, is associated with limited treatment options and hence poor prognosis. We have previously demonstrated that the αVβ3 integrin is over-expressed in neuroendocrine prostate cancer. We now show that LM609, a monoclonal antibody that specifically targets the human αVβ3 integrin, hinders the growth of neuroendocrine prostate cancer patient-derived xenografts in vivo. Our group has recently identified a novel αVβ3 integrin binding partner, NgR2, responsible for regulating the expression of neuroendocrine markers and for inducing neuroendocrine differentiation in prostate cancer cells. Through in vitro functional assays, we here demonstrate that NgR2 is crucial in promoting cell adhesion to αVβ3 ligands. Moreover, we describe for the first time co-fractionation of αVβ3 integrin and NgR2 in small extracellular vesicles derived from metastatic prostate cancer patients plasma. These prostate cancer patient-derived small extracellular vesicles have a functional impact on human monocytes, increasing their adhesion to fibronectin. The monocytes incubated with small extracellular vesicles do not show an associated change in conventional polarization marker expression and appear to be in an early stage that may be defined as adhesion competent. Overall, these findings allow us to better understand integrin-directed signaling and cell-cell communication during cancer progression. Furthermore, our results pave the way for new diagnostic and therapeutic perspectives for patients affected by neuroendocrine prostate cancer.

Published

2023

7. Prostate lineage-specific metabolism governs luminal differentiation and response to antiandrogen treatment

Author

Giafaglione, Jenna M, Crowell, Preston D, Delcourt, Amelie ML, Hashimoto, Takao, Ha, Sung Min, Atmakuri, Aishwarya, Nunley, Nicholas M, Dang, Rachel MA, Tian, Mao, Diaz, Johnny A, Tika, Elisavet, Payne, Marie C, Burkhart, Deborah L, Li, Dapei, Navone, Nora M, Corey, Eva, Nelson, Peter S, Lin, Neil YC, Blanpain, Cedric, Ellis, Leigh, Boutros, Paul C, and Goldstein, Andrew S

Subjects

Biochemistry and Cell Biology, Biological Sciences, Urologic Diseases, Prostate Cancer, Aging, Cancer, Aetiology, 1.1 Normal biological development and functioning, 2.1 Biological and endogenous factors, Underpinning research, Male, Humans, Prostate, Monocarboxylic Acid Transporters, Cell Differentiation, Epithelial Cells, Androgen Antagonists, Lactates, Medical and Health Sciences, Developmental Biology, Biochemistry and cell biology

Abstract

Lineage transitions are a central feature of prostate development, tumourigenesis and treatment resistance. While epigenetic changes are well known to drive prostate lineage transitions, it remains unclear how upstream metabolic signalling contributes to the regulation of prostate epithelial identity. To fill this gap, we developed an approach to perform metabolomics on primary prostate epithelial cells. Using this approach, we discovered that the basal and luminal cells of the prostate exhibit distinct metabolomes and nutrient utilization patterns. Furthermore, basal-to-luminal differentiation is accompanied by increased pyruvate oxidation. We establish the mitochondrial pyruvate carrier and subsequent lactate accumulation as regulators of prostate luminal identity. Inhibition of the mitochondrial pyruvate carrier or supplementation with exogenous lactate results in large-scale chromatin remodelling, influencing both lineage-specific transcription factors and response to antiandrogen treatment. These results establish reciprocal regulation of metabolism and prostate epithelial lineage identity.

Published

2023

8. ACAA2 is a novel molecular indicator for cancers with neuroendocrine phenotype.

Author

Shen, Michelle, Toland, Angus, Hsu, En-Chi, Hartono, Alifiani, Alabi, Busola, Aslan, Merve, Nguyen, Holly, Sessions, Conner, Shi, Chanjuan, Huang, Jiaoti, Brooks, James, Corey, Eva, Nolley, Rosie, Stoyanova, Tanya, and Liu, Shiqin

Subjects

Humans, Male, Carcinoma, Neuroendocrine, Carcinoma, Small Cell, Cell Line, Tumor, Lung Neoplasms, Phenotype, Prostatic Neoplasms, RNA, Messenger, Small Cell Lung Carcinoma

Abstract

BACKGROUND: Neuroendocrine phenotype is commonly associated with therapy resistance and poor prognoses in small-cell neuroendocrine cancers (SCNCs), such as neuroendocrine prostate cancer (NEPC) and small-cell lung cancer (SCLC). Expression levels of current neuroendocrine markers exhibit high case-by-case variability, so multiple markers are used in combination to identify SCNCs. Here, we report that ACAA2 is elevated in SCNCs and is a potential molecular indicator for SCNCs. METHODS: ACAA2 expressions in tumour xenografts, tissue microarrays (TMAs), and patient tissues from prostate and lung cancers were analysed via immunohistochemistry. ACAA2 mRNA levels in lung and prostate cancer (PC) patients were assessed in published datasets. RESULTS: ACAA2 protein and mRNA levels were elevated in SCNCs relative to non-SCNCs. Medium/high ACAA2 intensity was observed in 78% of NEPC PDXs samples (N = 27) relative to 33% of adeno-CRPC (N = 86), 2% of localised PC (N = 50), and 0% of benign prostate specimens (N = 101). ACAA2 was also elevated in lung cancer patient tissues with neuroendocrine phenotype. 83% of lung carcinoid tissues (N = 12) and 90% of SCLC tissues (N = 10) exhibited medium/high intensity relative to 40% of lung adenocarcinoma (N = 15). CONCLUSION: ACAA2 expression is elevated in aggressive SCNCs such as NEPC and SCLC, suggesting it is a potential molecular indicator for SCNCs.

Published

2023

9. Novel inhibition of AKR1C3 and androgen receptor axis by PTUPB synergizes enzalutamide treatment in advanced prostate cancer

Author

Yang, Joy C, Xu, Pengfei, Ning, Shu, Wasielewski, Logan J, Adomat, Hans, Hwang, Sung Hee, Morisseau, Christophe, Gleave, Martin, Corey, Eva, Gao, Allen C, Lara Jr, Primo N, Evans, Christopher P, Hammock, Bruce D, and Liu, Chengfei

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Cancer, Urologic Diseases, Prostate Cancer, 5.1 Pharmaceuticals, Good Health and Well Being, Male, Humans, Receptors, Androgen, Prostatic Neoplasms, Castration-Resistant, Drug Resistance, Neoplasm, Cell Line, Tumor, Nitriles, Androgen Receptor Antagonists, Aldo-Keto Reductase Family 1 Member C3, Oncology & Carcinogenesis, Biochemistry and cell biology, Oncology and carcinogenesis

Abstract

Castration-resistant prostate cancer (CRPC) is the main driving force of mortality in prostate cancer patients. Among the parameters contributing to the progression of CRPC and treatment failure, elevation of the steroidogenic enzyme AKR1C3 and androgen receptor variant 7 (AR-V7) are frequently reported. The AKR1C3/AR-V7 complex has been recognized as a major driver for drug resistance in advanced prostate cancer. Herein we report that the level of AKR1C3 is reciprocally regulated by the full-length androgen receptor (AR-FL) through binding to the distal enhancer region of the AKR1C3 gene. A novel function of PTUPB in AKR1C3 inhibition was discovered and PTUPB showed more effectiveness than indomethacin and celecoxib in suppressing AKR1C3 activity and CRPC cell growth. PTUPB synergizes with enzalutamide treatment in tumor suppression and gene signature regulation. Combination treatments with PTUPB and enzalutamide provide benefits by blocking AR/AR-V7 signaling, which inhibits the growth of castration relapsed VCaP xenograft tumors and patient-derived xenograft organoids. Targeting of the ARK1C3/AR/AR-V7 axis with PTUPB and enzalutamide may overcome drug resistance to AR signaling inhibitors in advanced prostate cancer.

Published

2023

10. Activation of neural lineage networks and ARHGEF2 in enzalutamide-resistant and neuroendocrine prostate cancer and association with patient outcomes

Author

Ning, Shu, Zhao, Jinge, Lombard, Alan P, D’Abronzo, Leandro S, Leslie, Amy R, Sharifi, Masuda, Lou, Wei, Liu, Chengfei, Yang, Joy C, Evans, Christopher P, Corey, Eva, Chen, Hong-Wu, Yu, Aiming, Ghosh, Paramita M, and Gao, Allen C

Subjects

Biomedical and Clinical Sciences, Clinical Sciences, Oncology and Carcinogenesis, Prostate Cancer, Urologic Diseases, Stem Cell Research, Clinical Research, Stem Cell Research - Nonembryonic - Human, Cancer, Genetics, Detection, screening and diagnosis, Aetiology, 4.1 Discovery and preclinical testing of markers and technologies, 2.1 Biological and endogenous factors, Prostate, Prostate cancer

Abstract

BackgroundTreatment-emergent neuroendocrine prostate cancer (NEPC) after androgen receptor (AR) targeted therapies is an aggressive variant of prostate cancer with an unfavorable prognosis. The underlying mechanisms for early neuroendocrine differentiation are poorly defined and diagnostic and prognostic biomarkers are needed.MethodsWe performed transcriptomic analysis on the enzalutamide-resistant prostate cancer cell line C4-2B MDVR and NEPC patient databases to identify neural lineage signature (NLS) genes. Correlation of NLS genes with clinicopathologic features was determined. Cell viability was determined in C4-2B MDVR and H660 cells after knocking down ARHGEF2 using siRNA. Organoid viability of patient-derived xenografts was measured after knocking down ARHGEF2.ResultsWe identify a 95-gene NLS representing the molecular landscape of neural precursor cell proliferation, embryonic stem cell pluripotency, and neural stem cell differentiation, which may indicate an early or intermediate stage of neuroendocrine differentiation. These NLS genes positively correlate with conventional neuroendocrine markers such as chromogranin and synaptophysin, and negatively correlate with AR and AR target genes in advanced prostate cancer. Differentially expressed NLS genes stratify small-cell NEPC from prostate adenocarcinoma, which are closely associated with clinicopathologic features such as Gleason Score and metastasis status. Higher ARGHEF2, LHX2, and EPHB2 levels among the 95 NLS genes correlate with a shortened survival time in NEPC patients. Furthermore, downregulation of ARHGEF2 gene expression suppresses cell viability and markers of neuroendocrine differentiation in enzalutamide-resistant and neuroendocrine cells.ConclusionsThe 95 neural lineage gene signatures capture an early molecular shift toward neuroendocrine differentiation, which could stratify advanced prostate cancer patients to optimize clinical treatment and serve as a source of potential therapeutic targets in advanced prostate cancer.

Published

2022

11. Cholinergic signaling via muscarinic M1 receptor confers resistance to docetaxel in prostate cancer

Author

Wang, Jing, Wei, Jing, Pu, Tianjie, Zeng, Alan, Karthikeyan, Varsha, Bechtold, Baron, Vo, Karen, Chen, Jingrui, Lin, Tzu-Ping, Chang, Amy P., Corey, Eva, Puhr, Martin, Klocker, Helmut, Culig, Zoran, Bland, Tyler, and Wu, Boyang Jason

Published

2024

12. Temporal evolution reveals bifurcated lineages in aggressive neuroendocrine small cell prostate cancer trans-differentiation

Author

Chen, Chia-Chun, Tran, Wendy, Song, Kai, Sugimoto, Tyler, Obusan, Matthew B., Wang, Liang, Sheu, Katherine M., Cheng, Donghui, Ta, Lisa, Varuzhanyan, Grigor, Huang, Arthur, Xu, Runzhe, Zeng, Yuanhong, Borujerdpur, Amirreza, Bayley, Nicholas A., Noguchi, Miyako, Mao, Zhiyuan, Morrissey, Colm, Corey, Eva, Nelson, Peter S., Zhao, Yue, Huang, Jiaoti, Park, Jung Wook, Witte, Owen N., and Graeber, Thomas G.

Published

2023

13. Multi-level functional genomics reveals molecular and cellular oncogenicity of patient-based 3′ untranslated region mutations

Author

Schuster, Samantha L., Arora, Sonali, Wladyka, Cynthia L., Itagi, Pushpa, Corey, Lukas, Young, Dave, Stackhouse, Bethany L., Kollath, Lori, Wu, Qian V., Corey, Eva, True, Lawrence D., Ha, Gavin, Paddison, Patrick J., and Hsieh, Andrew C.

Published

2023

14. Tumor-derived biomarkers predict efficacy of B7H3 antibody-drug conjugate treatment in metastatic prostate cancer models

Author

Agarwal, Supreet, Fang, Lei, McGowen, Kerry, Yin, JuanJuan, Bowman, Joel, Ku, Anson T., Alilin, Aian Neil, Corey, Eva, Roudier, Martine P., True, Lawrence D., Dumpit, Ruth, Coleman, Ilsa, Lee, John K., Nelson, Peter S., Capaldo, Brian J., Mariani, Aida, Hoover, Clare, Senatorov, Ilya S., Beshiri, Michael, Sowalsky, Adam G., Hurt, Elaine M., and Kelly, Kathleen

Subjects

United States. National Cancer Institute -- Analysis, AstraZeneca PLC, Biopharmaceutics -- Health aspects -- Analysis, Tumor proteins -- Drug therapy, Prostate cancer -- Drug therapy, Antineoplastic agents -- Health aspects -- Analysis, Metastasis -- Drug therapy, Viral antibodies -- Health aspects -- Analysis, Antigens -- Analysis -- Health aspects, Antibodies -- Health aspects -- Analysis, Biological markers -- Health aspects -- Analysis, Pharmaceutical industry -- Health aspects -- Analysis, Antimitotic agents -- Health aspects -- Analysis, Health care industry

Abstract

Antibody-drug conjugates (ADCs) are a promising targeted cancer therapy; however, patient selection based solely on target antigen expression without consideration for cytotoxic payload vulnerabilities has plateaued clinical benefits. Biomarkers to capture patients who might benefit from specific ADCs have not been systematically determined for any cancer. We present a comprehensive therapeutic and biomarker analysis of a B7H3-ADC with pyrrolobenzodiazepine(PBD) payload in 26 treatment- resistant, metastatic prostate cancer (mPC) models. B7H3 is a tumor-specific surface protein widely expressed in mPC, and PBD is a DNA cross-linking agent. B7H3 expression was necessary but not sufficient for B7H3-PBD-ADC responsiveness. RB1 deficiency and/or replication stress, characteristics of poor prognosis, and conferred sensitivity were associated with complete tumor regression in both neuroendocrine (NEPC) and androgen receptor positive (ARPC) prostate cancer models, even with low B7H3 levels. Non-ARPC models, which are currently lacking efficacious treatment, demonstrated the highest replication stress and were most sensitive to treatment. In RB1 WT ARPC tumors, SLFN11 expression or select DNA repair mutations in SLFN11 nonexpressors governed response. Importantly, WT TP53 predicted nonresponsiveness (7 of 8 models). Overall, biomarker-focused selection of models led to high efficacy of in vivo treatment. These data enable a paradigm shift to biomarker-driven trial designs for maximizing clinical benefit of ADC therapies., Introduction Metastatic prostate cancer (mPC) remains a lethal disease accounting for more than 30,000 deaths annually in the United States (1). The use of androgen deprivation therapy (ADT) and androgen [...]

Published

2023

15. GD2 and its biosynthetic enzyme GD3 synthase promote tumorigenesis in prostate cancer by regulating cancer stem cell behavior

Author

Bhat, Aaqib M., primary, Mohapatra, Bhopal C., additional, Luan, Haitao, additional, Mushtaq, Insha, additional, Chakraborty, Sukanya, additional, Kumar, Siddhartha, additional, Wu, Wangbin, additional, Nolan, Ben, additional, Dutta, Samikshan, additional, Storck, Matthew D., additional, Schott, Micah, additional, Meza, Jane L., additional, Lele, Subodh M., additional, Lin, Ming-Fong, additional, Cook, Leah M., additional, Corey, Eva, additional, Morrissey, Colm, additional, Coulter, Donald W., additional, Rowley, M. Jordan, additional, Natarajan, Amarnath, additional, Datta, Kaustubh, additional, Band, Vimla, additional, and Band, Hamid, additional

Published

2024

16. HOXB13 suppresses de novo lipogenesis through HDAC3-mediated epigenetic reprogramming in prostate cancer

Author

Lu, Xiaodong, Fong, Ka-wing, Gritsina, Galina, Wang, Fang, Baca, Sylvan C., Brea, Lourdes T., Berchuck, Jacob E., Spisak, Sandor, Ross, Jenny, Morrissey, Colm, Corey, Eva, Chandel, Navdeep S., Catalona, William J., Yang, Ximing, Freedman, Matthew L., Zhao, Jonathan C., and Yu, Jindan

Published

2022

17. The NOGO receptor NgR2, a novel αVβ3 integrin effector, induces neuroendocrine differentiation in prostate cancer

Author

Quaglia, Fabio, Krishn, Shiv Ram, Sossey-Alaoui, Khalid, Rana, Priyanka Shailendra, Pluskota, Elzbieta, Park, Pyung Hun, Shields, Christopher D., Lin, Stephen, McCue, Peter, Kossenkov, Andrew V., Wang, Yanqing, Goodrich, David W., Ku, Sheng-Yu, Beltran, Himisha, Kelly, William K., Corey, Eva, Klose, Maja, Bandtlow, Christine, Liu, Qin, Altieri, Dario C., Plow, Edward F., and Languino, Lucia R.

Published

2022

18. MYC drives aggressive prostate cancer by disrupting transcriptional pause release at androgen receptor targets

Author

Qiu, Xintao, Boufaied, Nadia, Hallal, Tarek, Feit, Avery, de Polo, Anna, Luoma, Adrienne M., Alahmadi, Walaa, Larocque, Janie, Zadra, Giorgia, Xie, Yingtian, Gu, Shengqing, Tang, Qin, Zhang, Yi, Syamala, Sudeepa, Seo, Ji-Heui, Bell, Connor, O’Connor, Edward, Liu, Yang, Schaeffer, Edward M., Jeffrey Karnes, R., Weinmann, Sheila, Davicioni, Elai, Morrissey, Colm, Cejas, Paloma, Ellis, Leigh, Loda, Massimo, Wucherpfennig, Kai W., Pomerantz, Mark M., Spratt, Daniel E., Corey, Eva, Freedman, Matthew L., Shirley Liu, X., Brown, Myles, Long, Henry W., and Labbé, David P.

Published

2022

19. Reformation of the chondroitin sulfate glycocalyx enables progression of AR-independent prostate cancer

Author

Al-Nakouzi, Nader, Wang, Chris Kedong, Oo, Htoo Zarni, Nelepcu, Irina, Lallous, Nada, Spliid, Charlotte B., Khazamipour, Nastaran, Lo, Joey, Truong, Sarah, Collins, Colin, Hui, Desmond, Esfandnia, Shaghayegh, Adomat, Hans, Clausen, Thomas Mandel, Gustavsson, Tobias, Choudhary, Swati, Dagil, Robert, Corey, Eva, Wang, Yuzhuo, Chauchereau, Anne, Fazli, Ladan, Esko, Jeffrey D., Salanti, Ali, Nelson, Peter S., Gleave, Martin E., and Daugaard, Mads

Published

2022

20. BCL2 expression is enriched in androgen receptor-negative advanced prostate cancer

Author

Jimenez-Vacas, Juan M, primary, Westaby, Daniel, additional, Figueiredo, Ines, additional, Rekowski, Jan, additional, Pettinger, Claire, additional, Gurel, Bora, additional, Bogdan, Denisa, additional, Buroni, Lorenzo, additional, Neeb, Antje, additional, Padilha, Ana, additional, Taylor, Joe, additional, Zeng, Wanting, additional, Das, Souvik, additional, Hobern, Emily, additional, Riisnaes, Ruth, additional, Crespo, Mateus, additional, Miranda, Susana, additional, Ferreira, Ana, additional, Hanratty, Brian, additional, Nava, Rodrigues Daniel, additional, Bertan, Claudia, additional, Seed, George, additional, Fenor, de La Maza Maria de Los Dolores, additional, Guo, Christina, additional, Carmichael, Juliet, additional, Grochot, Rafael, additional, Chandran, Khobe, additional, Stavridi, Anastasia, additional, Varkaris, Andreas, additional, Stylianou, Nataly, additional, Hollier, Brett, additional, Tunariu, Nina, additional, Balk, Steven, additional, Carreira, Suzanne, additional, Yuan, Wei, additional, Nelson, Peter, additional, Corey, Eva, additional, Haffner, Michael, additional, de, Bono Johann, additional, and Sharp, Adam, additional

Published

2024

21. Plexin D1 emerges as a novel target in the development of neural lineage plasticity in treatment-resistant prostate cancer

Author

Liu, Chengfei, primary, Chen, Bo, additional, Xu, Pengfei, additional, Yang, Joy, additional, Nip, Christopher, additional, Wang, Leyi, additional, Shen, Yuqiu, additional, Ning, Shu, additional, Shang, Yufeng, additional, Corey, Eva, additional, Gao, Allen C., additional, Gestwicki, Jason, additional, Wei, Qiang, additional, and Liu, Liangren, additional

Published

2024

22. BET inhibitors as a therapeutic intervention in gastrointestinal gene signature-positive castration-resistant prostate cancer

Author

Shukla, Shipra, primary, Li, Dan, additional, Nguyen, Holly, additional, Conner, Jennifer, additional, Bayshtok, Gabriella, additional, Cho, Woo Hyun, additional, Pachai, Mohini, additional, Teri, Nicholas, additional, Campeau, Eric, additional, Attwell, Sarah, additional, Trojer, Patrick, additional, Ostrovnaya, Irina, additional, Gopalan, Anuradha, additional, Corey, Eva, additional, Chi, Ping, additional, and Chen, Yu, additional

Published

2024

23. Supplementary Tables S1-S10 from Noninvasive Detection of Neuroendocrine Prostate Cancer through Targeted Cell-free DNA Methylation

Author

Franceschini, Gian Marco, primary, Quaini, Orsetta, primary, Mizuno, Kei, primary, Orlando, Francesco, primary, Ciani, Yari, primary, Ku, Sheng-Yu, primary, Sigouros, Michael, primary, Rothmann, Emily, primary, Alonso, Alicia, primary, Benelli, Matteo, primary, Nardella, Caterina, primary, Auh, Joonghoon, primary, Freeman, Dory, primary, Hanratty, Brian, primary, Adil, Mohamed, primary, Elemento, Olivier, primary, Tagawa, Scott T., primary, Feng, Felix Y., primary, Caffo, Orazio, primary, Buttigliero, Consuelo, primary, Basso, Umberto, primary, Nelson, Peter S., primary, Corey, Eva, primary, Haffner, Michael C., primary, Attard, Gerhardt, primary, Aparicio, Ana, primary, Demichelis, Francesca, primary, and Beltran, Himisha, primary

Published

2024

24. Data from Noninvasive Detection of Neuroendocrine Prostate Cancer through Targeted Cell-free DNA Methylation

Author

Franceschini, Gian Marco, primary, Quaini, Orsetta, primary, Mizuno, Kei, primary, Orlando, Francesco, primary, Ciani, Yari, primary, Ku, Sheng-Yu, primary, Sigouros, Michael, primary, Rothmann, Emily, primary, Alonso, Alicia, primary, Benelli, Matteo, primary, Nardella, Caterina, primary, Auh, Joonghoon, primary, Freeman, Dory, primary, Hanratty, Brian, primary, Adil, Mohamed, primary, Elemento, Olivier, primary, Tagawa, Scott T., primary, Feng, Felix Y., primary, Caffo, Orazio, primary, Buttigliero, Consuelo, primary, Basso, Umberto, primary, Nelson, Peter S., primary, Corey, Eva, primary, Haffner, Michael C., primary, Attard, Gerhardt, primary, Aparicio, Ana, primary, Demichelis, Francesca, primary, and Beltran, Himisha, primary

Published

2024

25. Supplementary Figures S1-S7 from Noninvasive Detection of Neuroendocrine Prostate Cancer through Targeted Cell-free DNA Methylation

Author

Franceschini, Gian Marco, primary, Quaini, Orsetta, primary, Mizuno, Kei, primary, Orlando, Francesco, primary, Ciani, Yari, primary, Ku, Sheng-Yu, primary, Sigouros, Michael, primary, Rothmann, Emily, primary, Alonso, Alicia, primary, Benelli, Matteo, primary, Nardella, Caterina, primary, Auh, Joonghoon, primary, Freeman, Dory, primary, Hanratty, Brian, primary, Adil, Mohamed, primary, Elemento, Olivier, primary, Tagawa, Scott T., primary, Feng, Felix Y., primary, Caffo, Orazio, primary, Buttigliero, Consuelo, primary, Basso, Umberto, primary, Nelson, Peter S., primary, Corey, Eva, primary, Haffner, Michael C., primary, Attard, Gerhardt, primary, Aparicio, Ana, primary, Demichelis, Francesca, primary, and Beltran, Himisha, primary

Published

2024

26. Unveiling novel double-negative prostate cancer subtypes through single-cell RNA sequencing analysis.

Author

Cheng, Siyuan, Li, Lin, Yeh, Yunshin, Shi, Yingli, Franco, Omar, Corey, Eva, and Yu, Xiuping

Subjects

RNA sequencing, GENE expression, WEB-based user interfaces, CELL populations, PROSTATE cancer, CANCER invasiveness

Abstract

Recent advancements in single-cell RNA sequencing (scRNAseq) have facilitated the discovery of previously unrecognized subtypes within prostate cancer (PCa), offering new insights into cancer heterogeneity and progression. In this study, we integrated scRNAseq data from multiple studies, comprising publicly available cohorts and data generated by our research team, and established the Human Prostate Single cell Atlas (HuPSA) and Mouse Prostate Single cell Atlas (MoPSA) datasets. Through comprehensive analysis, we identified two novel double-negative PCa populations: KRT7 cells characterized by elevated KRT7 expression and progenitor-like cells marked by SOX2 and FOXA2 expression, distinct from NEPCa, and displaying stem/progenitor features. Furthermore, HuPSA-based deconvolution re-classified human PCa specimens, validating the presence of these novel subtypes. We then developed a user-friendly web application, "HuPSA–MoPSA" (https://pcatools.shinyapps.io/HuPSA-MoPSA/), for visualizing gene expression across all newly established datasets. Our study provides comprehensive tools for PCa research and uncovers novel cancer subtypes that can inform clinical diagnosis and treatment strategies. [ABSTRACT FROM AUTHOR]

Published

2024

27. Reproducible preclinical models of androgen receptor driven human prostate cancer bone metastasis.

Author

Yin, JuanJuan, Daryanani, Asha, Lu, Fan, Ku, Anson T., Bright, John R., Alilin, Aian Neil S., Bowman, Joel, Lake, Ross, Li, Chennan, Truong, Tri M., Twohig, Joseph D., Mostaghel, Elahe A., Ishikawa, Masaki, Simpson, Mark, Trostel, Shana Y., Corey, Eva, Sowalsky, Adam G., and Kelly, Kathleen

Published

2024

28. Imaging and quantification of prostate cancer-associated bone by polarization-sensitive optical coherence tomography

Author

Zhou, Chris, primary, Jung, Naomi, additional, Xu, Samuel, additional, Eltit-Guersetti, Felipe, additional, Lu, Xin, additional, Wang, Qiong, additional, Liang, Doris, additional, Morrissey, Colm, additional, Corey, Eva, additional, True, Lawrence D., additional, Wang, Rizhi, additional, Tang, Shuo, additional, and Cox, Michael E., additional

Published

2024

29. LSD1 inhibition suppresses ASCL1 and de-represses YAP1 to drive potent activity against neuroendocrine prostate cancer

Author

Mandl, Adel, primary, Jasmine, Sumer, additional, Krueger, Tim E. G., additional, Kumar, Rajendra, additional, Coleman, Ilsa M., additional, Dalrymple, Susan L., additional, Antony, Lizamma, additional, Rosen, D. Marc, additional, Jing, Yuezhou, additional, Hanratty, Brian, additional, Patel, Radhika A., additional, Low, Jin-Yih, additional, Dias, Jennifer, additional, Celatka, Cassandra A., additional, Tapper, Amy E., additional, Kleppe, Maria, additional, Kanayama, Mayuko, additional, Speranzini, Valentina, additional, Wang, Yuzhuo, additional, Luo, Jun, additional, Corey, Eva, additional, Sena, Laura A., additional, Casero, Robert A., additional, Lotan, Tamara, additional, Trock, Bruce J, additional, Kachhap, Sushant K., additional, Denmeade, Samuel R., additional, Carducci, Michael A., additional, Mattevi, Andrea, additional, Haffner, Michael C., additional, Nelson, Peter S., additional, Rienhoff, Hugh HY, additional, Isaacs, John T., additional, and Brennen, W. Nathaniel, additional

Published

2024

30. Dual targeting of the androgen receptor and PI3K/AKT/mTOR pathways in prostate cancer models improves antitumor efficacy and promotes cell apoptosis

Author

Sugawara, Tatsuo, primary, Nevedomskaya, Ekaterina, additional, Heller, Simon, additional, Böhme, Annika, additional, Lesche, Ralf, additional, von Ahsen, Oliver, additional, Grünewald, Sylvia, additional, Nguyen, Holly M., additional, Corey, Eva, additional, Baumgart, Simon J., additional, Georgi, Victoria, additional, Pütter, Vera, additional, Fernández‐Montalván, Amaury, additional, Vasta, James D., additional, Robers, Matthew B., additional, Politz, Oliver, additional, Mumberg, Dominik, additional, and Haendler, Bernard, additional

Published

2024

31. Assessment of Cell Surface Targets in Metastatic Prostate Cancer: Expression Landscape and Molecular Correlates

Author

Haffner, Michael, primary, Ajkunic, Azra, additional, Sayar, Erolcan, additional, Roudier, Martine, additional, Patel, Radhika, additional, Coleman, Ilsa, additional, Sarkar, Navonil, additional, Hanratty, Brian, additional, Adil, Mohamed, additional, Zhao, Jimmy, additional, Zaidi, Samir, additional, True, Larry, additional, Sperger, Jamie, additional, Cheng, Heather, additional, Yu, Evan, additional, Montgomery, Robert, additional, Hawley, Jessica, additional, Ha, Gavin, additional, Lee, John, additional, Harmon, Stephanie, additional, Corey, Eva, additional, Lang, Joshua, additional, Sawyers, Charles, additional, Morrissey, Colm, additional, Schweizer, Michael, additional, Gulati, Roman, additional, and Nelson, Peter, additional

Published

2023

32. 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 A. S., 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.

Published

2021

33. Subtype heterogeneity and epigenetic convergence in neuroendocrine prostate cancer

Author

Cejas, Paloma, Xie, Yingtian, Font-Tello, Alba, Lim, Klothilda, Syamala, Sudeepa, Qiu, Xintao, Tewari, Alok K., Shah, Neel, Nguyen, Holly M., Patel, Radhika A., Brown, Lisha, Coleman, Ilsa, Hackeng, Wenzel M., Brosens, Lodewijk, Dreijerink, Koen M. A., Ellis, Leigh, Alaiwi, Sarah Abou, Seo, Ji-Heui, Baca, Sylvan, Beltran, Himisha, Khani, Francesca, Pomerantz, Mark, Dall’Agnese, Alessandra, Crowdis, Jett, Van Allen, Eliezer M., Bellmunt, Joaquim, Morrisey, Colm, Nelson, Peter S., DeCaprio, James, Farago, Anna, Dyson, Nicholas, Drapkin, Benjamin, Liu, X. Shirley, Freedman, Matthew, Haffner, Michael C., Corey, Eva, Brown, Myles, and Long, Henry W.

Published

2021

34. MCM2-7 complex is a novel druggable target for neuroendocrine prostate cancer

Author

Hsu, En-Chi, Shen, Michelle, Aslan, Merve, Liu, Shiqin, Kumar, Manoj, Garcia-Marques, Fernando, Nguyen, Holly M., Nolley, Rosalie, Pitteri, Sharon J., Corey, Eva, Brooks, James D., and Stoyanova, Tanya

Published

2021

35. A bladder cancer patient-derived xenograft displays aggressive growth dynamics in vivo and in organoid culture

Author

Cai, Elise Y., Garcia, Jose, Liu, Yuzhen, Vakar-Lopez, Funda, Arora, Sonali, Nguyen, Holly M., Lakely, Bryce, Brown, Lisha, Wong, Alicia, Montgomery, Bruce, Lee, John K., Corey, Eva, Wright, Jonathan L., Hsieh, Andrew C., and Lam, Hung-Ming

Published

2021

36. Dynamic prostate cancer transcriptome analysis delineates the trajectory to disease progression

Author

Bolis, Marco, Bossi, Daniela, Vallerga, Arianna, Ceserani, Valentina, Cavalli, Manuela, Impellizzieri, Daniela, Di Rito, Laura, Zoni, Eugenio, Mosole, Simone, Elia, Angela Rita, Rinaldi, Andrea, Pereira Mestre, Ricardo, D’Antonio, Eugenia, Ferrari, Matteo, Stoffel, Flavio, Jermini, Fernando, Gillessen, Silke, Bubendorf, Lukas, Schraml, Peter, Calcinotto, Arianna, Corey, Eva, Moch, Holger, Spahn, Martin, Thalmann, George, Kruithof-de Julio, Marianna, Rubin, Mark A., and Theurillat, Jean-Philippe P.

Published

2021

37. Multiplexed functional genomic analysis of 5’ untranslated region mutations across the spectrum of prostate cancer

Author

Lim, Yiting, Arora, Sonali, Schuster, Samantha L., Corey, Lukas, Fitzgibbon, Matthew, Wladyka, Cynthia L., Wu, Xiaoying, Coleman, Ilsa M., Delrow, Jeffrey J., Corey, Eva, True, Lawrence D., Nelson, Peter S., Ha, Gavin, and Hsieh, Andrew C.

Published

2021

38. Supplementary Figure 14 from Concurrent Targeting of HDAC and PI3K to Overcome Phenotypic Heterogeneity of Castration-resistant and Neuroendocrine Prostate Cancers

Author

Zhang, Ailin, primary, Lau, Nathan A., primary, Wong, Alicia, primary, Brown, Lisha G., primary, Coleman, Ilsa M., primary, De Sarkar, Navonil, primary, Li, Dapei, primary, DeLucia, Diana C., primary, Labrecque, Mark P., primary, Nguyen, Holly M., primary, Conner, Jennifer L., primary, Dumpit, Ruth F., primary, True, Lawrence D., primary, Lin, Daniel W., primary, Corey, Eva, primary, Alumkal, Joshi J., primary, Nelson, Peter S., primary, Morrissey, Colm, primary, and Lee, John K., primary

Published

2023

39. Supplementary Figure 8 from Concurrent Targeting of HDAC and PI3K to Overcome Phenotypic Heterogeneity of Castration-resistant and Neuroendocrine Prostate Cancers

Author

Zhang, Ailin, primary, Lau, Nathan A., primary, Wong, Alicia, primary, Brown, Lisha G., primary, Coleman, Ilsa M., primary, De Sarkar, Navonil, primary, Li, Dapei, primary, DeLucia, Diana C., primary, Labrecque, Mark P., primary, Nguyen, Holly M., primary, Conner, Jennifer L., primary, Dumpit, Ruth F., primary, True, Lawrence D., primary, Lin, Daniel W., primary, Corey, Eva, primary, Alumkal, Joshi J., primary, Nelson, Peter S., primary, Morrissey, Colm, primary, and Lee, John K., primary

Published

2023

40. Data from Concurrent Targeting of HDAC and PI3K to Overcome Phenotypic Heterogeneity of Castration-resistant and Neuroendocrine Prostate Cancers

Author

Zhang, Ailin, primary, Lau, Nathan A., primary, Wong, Alicia, primary, Brown, Lisha G., primary, Coleman, Ilsa M., primary, De Sarkar, Navonil, primary, Li, Dapei, primary, DeLucia, Diana C., primary, Labrecque, Mark P., primary, Nguyen, Holly M., primary, Conner, Jennifer L., primary, Dumpit, Ruth F., primary, True, Lawrence D., primary, Lin, Daniel W., primary, Corey, Eva, primary, Alumkal, Joshi J., primary, Nelson, Peter S., primary, Morrissey, Colm, primary, and Lee, John K., primary

Published

2023

41. Supplementary Table 3 from Concurrent Targeting of HDAC and PI3K to Overcome Phenotypic Heterogeneity of Castration-resistant and Neuroendocrine Prostate Cancers

Author

Zhang, Ailin, primary, Lau, Nathan A., primary, Wong, Alicia, primary, Brown, Lisha G., primary, Coleman, Ilsa M., primary, De Sarkar, Navonil, primary, Li, Dapei, primary, DeLucia, Diana C., primary, Labrecque, Mark P., primary, Nguyen, Holly M., primary, Conner, Jennifer L., primary, Dumpit, Ruth F., primary, True, Lawrence D., primary, Lin, Daniel W., primary, Corey, Eva, primary, Alumkal, Joshi J., primary, Nelson, Peter S., primary, Morrissey, Colm, primary, and Lee, John K., primary

Published

2023

42. Supplementary Figure 5 from Concurrent Targeting of HDAC and PI3K to Overcome Phenotypic Heterogeneity of Castration-resistant and Neuroendocrine Prostate Cancers

Author

Zhang, Ailin, primary, Lau, Nathan A., primary, Wong, Alicia, primary, Brown, Lisha G., primary, Coleman, Ilsa M., primary, De Sarkar, Navonil, primary, Li, Dapei, primary, DeLucia, Diana C., primary, Labrecque, Mark P., primary, Nguyen, Holly M., primary, Conner, Jennifer L., primary, Dumpit, Ruth F., primary, True, Lawrence D., primary, Lin, Daniel W., primary, Corey, Eva, primary, Alumkal, Joshi J., primary, Nelson, Peter S., primary, Morrissey, Colm, primary, and Lee, John K., primary

Published

2023

43. Supplementary Figure 3 from Concurrent Targeting of HDAC and PI3K to Overcome Phenotypic Heterogeneity of Castration-resistant and Neuroendocrine Prostate Cancers

Author

Zhang, Ailin, primary, Lau, Nathan A., primary, Wong, Alicia, primary, Brown, Lisha G., primary, Coleman, Ilsa M., primary, De Sarkar, Navonil, primary, Li, Dapei, primary, DeLucia, Diana C., primary, Labrecque, Mark P., primary, Nguyen, Holly M., primary, Conner, Jennifer L., primary, Dumpit, Ruth F., primary, True, Lawrence D., primary, Lin, Daniel W., primary, Corey, Eva, primary, Alumkal, Joshi J., primary, Nelson, Peter S., primary, Morrissey, Colm, primary, and Lee, John K., primary

Published

2023

44. Supplementary Figure 6 from Concurrent Targeting of HDAC and PI3K to Overcome Phenotypic Heterogeneity of Castration-resistant and Neuroendocrine Prostate Cancers

Author

Zhang, Ailin, primary, Lau, Nathan A., primary, Wong, Alicia, primary, Brown, Lisha G., primary, Coleman, Ilsa M., primary, De Sarkar, Navonil, primary, Li, Dapei, primary, DeLucia, Diana C., primary, Labrecque, Mark P., primary, Nguyen, Holly M., primary, Conner, Jennifer L., primary, Dumpit, Ruth F., primary, True, Lawrence D., primary, Lin, Daniel W., primary, Corey, Eva, primary, Alumkal, Joshi J., primary, Nelson, Peter S., primary, Morrissey, Colm, primary, and Lee, John K., primary

Published

2023

45. Supplementary Table 1 from Concurrent Targeting of HDAC and PI3K to Overcome Phenotypic Heterogeneity of Castration-resistant and Neuroendocrine Prostate Cancers

Author

Zhang, Ailin, primary, Lau, Nathan A., primary, Wong, Alicia, primary, Brown, Lisha G., primary, Coleman, Ilsa M., primary, De Sarkar, Navonil, primary, Li, Dapei, primary, DeLucia, Diana C., primary, Labrecque, Mark P., primary, Nguyen, Holly M., primary, Conner, Jennifer L., primary, Dumpit, Ruth F., primary, True, Lawrence D., primary, Lin, Daniel W., primary, Corey, Eva, primary, Alumkal, Joshi J., primary, Nelson, Peter S., primary, Morrissey, Colm, primary, and Lee, John K., primary

Published

2023

46. Supplementary Figure 7 from Concurrent Targeting of HDAC and PI3K to Overcome Phenotypic Heterogeneity of Castration-resistant and Neuroendocrine Prostate Cancers

Author

Zhang, Ailin, primary, Lau, Nathan A., primary, Wong, Alicia, primary, Brown, Lisha G., primary, Coleman, Ilsa M., primary, De Sarkar, Navonil, primary, Li, Dapei, primary, DeLucia, Diana C., primary, Labrecque, Mark P., primary, Nguyen, Holly M., primary, Conner, Jennifer L., primary, Dumpit, Ruth F., primary, True, Lawrence D., primary, Lin, Daniel W., primary, Corey, Eva, primary, Alumkal, Joshi J., primary, Nelson, Peter S., primary, Morrissey, Colm, primary, and Lee, John K., primary

Published

2023

47. Supplementary Figure 9 from Concurrent Targeting of HDAC and PI3K to Overcome Phenotypic Heterogeneity of Castration-resistant and Neuroendocrine Prostate Cancers

Author

Zhang, Ailin, primary, Lau, Nathan A., primary, Wong, Alicia, primary, Brown, Lisha G., primary, Coleman, Ilsa M., primary, De Sarkar, Navonil, primary, Li, Dapei, primary, DeLucia, Diana C., primary, Labrecque, Mark P., primary, Nguyen, Holly M., primary, Conner, Jennifer L., primary, Dumpit, Ruth F., primary, True, Lawrence D., primary, Lin, Daniel W., primary, Corey, Eva, primary, Alumkal, Joshi J., primary, Nelson, Peter S., primary, Morrissey, Colm, primary, and Lee, John K., primary

Published

2023

48. TARGETING THE αVβ3/NgR2 PATHWAY IN NEUROENDOCRINE PROSTATE CANCER

Author

Testa, Anna, primary, Quaglia, Fabio, additional, Naranjo, Nicole M., additional, Verrillo, Cecilia E., additional, Shields, Christopher D., additional, Lin, Stephen, additional, Pickles, Maxwell W., additional, Hamza, Drini F., additional, Von Schalscha, Tami, additional, Cheresh, David A., additional, Leiby, Benjamin, additional, Liu, Qin, additional, Ding, Jianyi, additional, Kelly, William K., additional, Craig Hooper, D., additional, Corey, Eva, additional, Plow, Edward F., additional, Altieri, Dario C., additional, and Languino, Lucia R., additional

Published

2023

49. Characterization of HOXB13 expression patterns in localized and metastatic castration‐resistant prostate cancer

Author

Patel, Radhika A, primary, Sayar, Erolcan, additional, Coleman, Ilsa, additional, Roudier, Martine P, additional, Hanratty, Brian, additional, Low, Jin‐Yih, additional, Jaiswal, Neha, additional, Ajkunic, Azra, additional, Dumpit, Ruth, additional, Ercan, Caner, additional, Salama, Nina, additional, O'Brien, Valerie P, additional, Isaacs, William B, additional, Epstein, Jonathan I, additional, De Marzo, Angelo M, additional, Trock, Bruce J, additional, Luo, Jun, additional, Brennen, W Nathaniel, additional, Tretiakova, Maria, additional, Vakar‐Lopez, Funda, additional, True, Lawrence D, additional, Goodrich, David W, additional, Corey, Eva, additional, Morrissey, Colm, additional, Nelson, Peter S, additional, Hurley, Paula J, additional, Gulati, Roman, additional, and Haffner, Michael C, additional

Published

2023

50. Concurrent targeting of HDAC and PI3K to overcome phenotypic heterogeneity of castration-resistant and neuroendocrine prostate cancers

Author

Zhang, Ailin, primary, Lau, Nathan A, additional, Wong, Alicia, additional, Brown, Lisha G, additional, Coleman, Ilsa M., additional, De Sarkar, Navonil, additional, Li, Dapei, additional, DeLucia, Diana C, additional, Labrecque, Mark P., additional, Nguyen, Holly M, additional, Conner, Jennifer L, additional, Dumpit, Ruth F, additional, True, Lawrence D., additional, Lin, Daniel W, additional, Corey, Eva, additional, Alumkal, Joshi J., additional, Nelson, Peter S., additional, Morrissey, Colm, additional, and Lee, John K, additional

Published

2023