Your search keyword '"Brian W. Simons"' showing total 147 results

1. Convergent alterations in the tumor microenvironment of MYC-driven human and murine prostate cancer

Author

Mindy K. Graham, Rulin Wang, Roshan Chikarmane, Bulouere Abel, Ajay Vaghasia, Anuj Gupta, Qizhi Zheng, Jessica Hicks, Polina Sysa-Shah, Xin Pan, Nicole Castagna, Jianyong Liu, Jennifer Meyers, Alyza Skaist, Yan Zhang, Michael Rubenstein, Kornel Schuebel, Brian W. Simons, Charles J. Bieberich, William G. Nelson, Shawn E. Lupold, Theodore L. DeWeese, Angelo M. De Marzo, and Srinivasan Yegnasubramanian

Subjects

Science

Abstract

Abstract How prostate cancer cells and their precursors mediate changes in the tumor microenvironment (TME) to drive prostate cancer progression is unclear, in part due to the inability to longitudinally study the disease evolution in human tissues. To overcome this limitation, we perform extensive single-cell RNA-sequencing (scRNA-seq) and molecular pathology of the comparative biology between human prostate cancer and key stages in the disease evolution of a genetically engineered mouse model (GEMM) of prostate cancer. Our studies of human tissues reveal that cancer cell-intrinsic activation of MYC signaling is a common denominator across the well-known molecular and pathological heterogeneity of human prostate cancer. Cell communication network and pathway analyses in GEMMs show that MYC oncogene-expressing neoplastic cells, directly and indirectly, reprogram the TME during carcinogenesis, leading to a convergence of cell state alterations in neighboring epithelial, immune, and fibroblast cell types that parallel key findings in human prostate cancer.

Published

2024

2. [18F]-Labeled PARP-1 PET imaging of PSMA targeted alpha particle radiotherapy response

Author

Hanwen Zhang, Diane Abou, Peng Lu, Abbie Meghan Hasson, Alexandria Villmer, Nadia Benabdallah, Wen Jiang, David Ulmert, Sean Carlin, Buck E. Rogers, Norman F. Turtle, Michael R. McDevitt, Brian Baumann, Brian W. Simons, Farrokh Dehdashti, Dong Zhou, and Daniel L. J. Thorek

Subjects

Medicine, Science

Abstract

Abstract The growing interest and clinical translation of alpha particle (α) therapies brings with it new challenges to assess target cell engagement and to monitor therapeutic effect. Noninvasive imaging has great potential to guide α-treatment and to harness the potential of these agents in the complex environment of disseminated disease. Poly(ADP) ribose polymerase 1 (PARP-1) is among the most abundantly expressed DNA repair enzymes with key roles in multiple repair pathways—such as those induced by irradiation. Here, we used a third-generation PARP1-specific radiotracer, [18F]-PARPZ, to delineate castrate resistant prostate cancer xenografts. Following treatment with the clinically applied [225Ac]-PSMA-617, positron emission tomography was performed and correlative autoradiography and histology acquired. [18F]-PARPZ was able to distinguish treated from control (saline) xenografts by increased uptake. Kinetic analysis of tracer accumulation also suggests that the localization of the agent to sites of increased PARP-1 expression is a consequence of DNA damage response. Together, these data support expanded investigation of [18F]-PARPZ to facilitate clinical translation in the ⍺-therapy space.

Published

2022

3. K-Ras and p53 mouse model with molecular characteristics of human rhabdomyosarcoma and translational applications

Author

Kengo Nakahata, Brian W. Simons, Enrico Pozzo, Ryan Shuck, Lyazat Kurenbekova, Zachary Prudowsky, Kshiti Dholakia, Cristian Coarfa, Tajhal D. Patel, Lawrence A. Donehower, and Jason T. Yustein

Subjects

gemm, rhabdomyosarcoma, k-ras, syngeneic models, Medicine, Pathology, RB1-214

Abstract

Rhabdomyosarcoma (RMS) is the most common soft tissue sarcoma in children, with overall long-term survival rates of ∼65-70%. Thus, additional molecular insights and representative models are critical for identifying and evaluating new treatment modalities. Using MyoD-Cre-mediated introduction of mutant K-RasG12D and perturbations in p53, we developed a novel genetically engineered mouse model (GEMM) for RMS. The anatomic sites of primary RMS development recapitulated human disease, including tumors in the head, neck, extremities and abdomen. We confirmed RMS histology and diagnosis through Hematoxylin and Eosin staining, and positive immunohistochemical staining for desmin, myogenin, and phosphotungstic acid–Hematoxylin. Cell lines from GEMM tumors were established with the ability to engraft in immunocompetent mice with comparable histological and staining features as the primary tumors. Tail vein injection of cell lines had high metastatic potential to the lungs. Transcriptomic analyses of p53R172H/K-RasG12D GEMM-derived tumors showed evidence of high molecular homology with human RMS. Finally, pre-clinical use of these murine RMS lines showed similar therapeutic responsiveness to chemotherapy and targeted therapies as human RMS cell lines.

Published

2022

4. AIM1 is an actin-binding protein that suppresses cell migration and micrometastatic dissemination

Author

Michael C. Haffner, David M. Esopi, Alcides Chaux, Meltem Gürel, Susmita Ghosh, Ajay M. Vaghasia, Harrison Tsai, Kunhwa Kim, Nicole Castagna, Hong Lam, Jessica Hicks, Nicolas Wyhs, Debika Biswal Shinohara, Paula J. Hurley, Brian W. Simons, Edward M. Schaeffer, Tamara L. Lotan, William B. Isaacs, George J. Netto, Angelo M. De Marzo, William G. Nelson, Steven S. An, and Srinivasan Yegnasubramanian

Subjects

Science

Abstract

Invasion of malignant cells involves changes in cytoskeleton dynamics. Here the authors identify absent in melanoma 1 as an actin binding protein and show that it regulates cytoskeletal remodeling and cell migration in prostate epithelial cells, acting as a metastatic suppressor in cancer cells.

Published

2017

5. Supplementary Data TS5 from Microparticle Encapsulation of a Prostate-targeted Biologic for the Treatment of Liver Metastases in a Preclinical Model of Castration-resistant Prostate Cancer

Author

W. Nathaniel Brennen, John T. Isaacs, Samuel R. Denmeade, S. Peter Howard, Jeffrey M. Karp, Lei Zheng, Sudhir H. Ranganath, Heidi Kuang, Haoyue Lan, Andrew Pickering, D. Marc Rosen, Susan L. Dalrymple, Brian W. Simons, Nitin Joshi, Oren Levy, Lizamma Antony, and Oliver C. Rogers

Abstract

Tbl S5

Published

2023

6. Data from Stromal CAVIN1 Controls Prostate Cancer Microenvironment and Metastasis by Modulating Lipid Distribution and Inflammatory Signaling

Author

Marikki Laiho, Brian W. Simons, Elina Ikonen, Alan K. Meeker, W. Nathaniel Brennen, and Jin-Yih Low

Abstract

Lipid uptake occurs through caveolae, plasma membrane invaginations formed by caveolins (CAV) and caveolae-associated protein 1 (CAVIN1). Genetic alterations of CAV1N1 and CAV1 modify lipid metabolism and underpin lipodystrophy syndromes. Lipids contribute to tumorigenesis by providing fuel to cancer metabolism and supporting growth and signaling. Tumor stroma promotes tumor proliferation, invasion, and metastasis, but how stromal lipids influence these processes remain to be defined. Here, we show that stromal CAVIN1 regulates lipid abundance in the prostate cancer microenvironment and suppresses metastasis. We show that depletion of CAVIN1 in prostate stromal cells markedly reduces their lipid droplet accumulation and increases inflammation. Stromal cells lacking CAVIN1 enhance prostate cancer cell migration and invasion. Remarkably, they increase lipid uptake and M2 inflammatory macrophage infiltration in the primary tumors and metastasis to distant sites. Our data support the concept that stromal cells contribute to prostate cancer aggressiveness by modulating lipid content and inflammation in the tumor microenvironment.Implications:This study showed that stromal CAVIN1 suppresses prostate cancer metastasis by modulating tumor microenvironment, lipid content, and inflammatory response.

Published

2023

7. Supplementary Figure Legends from Bacterial Prostatitis Enhances 2-Amino-1-Methyl-6-Phenylimidazo[4,5-b]Pyridine (PhIP)–Induced Cancer at Multiple Sites

Author

Angelo M. De Marzo, William G. Nelson, Edward M. Schaeffer, Anthony J. Schaeffer, Brian W. Simons, Shu-Han Yu, Heidi Hempel, Kirstie Canene-Adams, and Karen S. Sfanos

Abstract

Supplementary Figure Legends

Published

2023

8. Supplementary Fig. S3 from Bacterial Prostatitis Enhances 2-Amino-1-Methyl-6-Phenylimidazo[4,5-b]Pyridine (PhIP)–Induced Cancer at Multiple Sites

Author

Angelo M. De Marzo, William G. Nelson, Edward M. Schaeffer, Anthony J. Schaeffer, Brian W. Simons, Shu-Han Yu, Heidi Hempel, Kirstie Canene-Adams, and Karen S. Sfanos

Abstract

Supplementary Figure S3. Body weight and food intake data.

Published

2023

9. Data from Bacterial Prostatitis Enhances 2-Amino-1-Methyl-6-Phenylimidazo[4,5-b]Pyridine (PhIP)–Induced Cancer at Multiple Sites

Author

Angelo M. De Marzo, William G. Nelson, Edward M. Schaeffer, Anthony J. Schaeffer, Brian W. Simons, Shu-Han Yu, Heidi Hempel, Kirstie Canene-Adams, and Karen S. Sfanos

Abstract

Dietary carcinogens, such as 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine (PhIP), and chronic inflammation have each been implicated as etiologic agents in prostate cancer. We hypothesized that bacterial prostatitis would accelerate PhIP-induced preinvasive lesions in the rat prostate. Male Fischer 344 rats were assigned into 4 groups: Control (untreated), PhIP (200 ppm in the diet for 20 weeks), Escherichia coli (E. coli, prostatic inoculation in week 10), or PhIP + E. coli. Study animals were monitored for a total of 52 weeks and were euthanized as necessary based on strict criteria for health status and tumor burden. Animals treated with E. coli initially developed acute and chronic inflammation in all lobes of the prostate, whereas inflammation was observed predominantly in the ventral lobe at time of death. PhIP + E. coli–treated animals exhibited a marked decrease in survival compared with PhIP-alone–treated animals as a result of an increase in the number of invasive cancers that developed at multiple sites, including the skin, small intestine, and Zymbal's gland. Despite their earlier mortality, PhIP + E. coli–treated animals developed an increased average number of precancerous lesions within the prostate compared with PhIP-treated animals, with a significantly increased Ki-67 index. Multiplexed serum cytokine analysis indicated an increase in the level of circulating IL6 and IL12 in PhIP + E. coli–treated animals. Elevated serum IL6 levels correlated with the development of precancerous lesions within the prostate. These results suggest that bacterial infections and dietary carcinogens, two conceivably preventable cancer risk factors, may synergistically promote tumorigenesis. Cancer Prev Res; 8(8); 683–92. ©2015 AACR.

Published

2023

10. Figure S3 from Microparticle Encapsulation of a Prostate-targeted Biologic for the Treatment of Liver Metastases in a Preclinical Model of Castration-resistant Prostate Cancer

Author

W. Nathaniel Brennen, John T. Isaacs, Samuel R. Denmeade, S. Peter Howard, Jeffrey M. Karp, Lei Zheng, Sudhir H. Ranganath, Heidi Kuang, Haoyue Lan, Andrew Pickering, D. Marc Rosen, Susan L. Dalrymple, Brian W. Simons, Nitin Joshi, Oren Levy, Lizamma Antony, and Oliver C. Rogers

Abstract

Fig. S3

Published

2023

11. Supplementary Figures 1-5 from Stromal CAVIN1 Controls Prostate Cancer Microenvironment and Metastasis by Modulating Lipid Distribution and Inflammatory Signaling

Author

Marikki Laiho, Brian W. Simons, Elina Ikonen, Alan K. Meeker, W. Nathaniel Brennen, and Jin-Yih Low

Abstract

Figure S1 shows cell growth and lipid distribution data. Figure S2 shows lipid distribution and invasion data. Figure S3 shows additional transcriptomic data. Figure S4 and S5 shows additional orthotopic data.

Published

2023

12. Supplementary Methods from Bacterial Prostatitis Enhances 2-Amino-1-Methyl-6-Phenylimidazo[4,5-b]Pyridine (PhIP)–Induced Cancer at Multiple Sites

Author

Angelo M. De Marzo, William G. Nelson, Edward M. Schaeffer, Anthony J. Schaeffer, Brian W. Simons, Shu-Han Yu, Heidi Hempel, Kirstie Canene-Adams, and Karen S. Sfanos

Abstract

Supplementary Methods file

Published

2023

13. Data from Microparticle Encapsulation of a Prostate-targeted Biologic for the Treatment of Liver Metastases in a Preclinical Model of Castration-resistant Prostate Cancer

Author

W. Nathaniel Brennen, John T. Isaacs, Samuel R. Denmeade, S. Peter Howard, Jeffrey M. Karp, Lei Zheng, Sudhir H. Ranganath, Heidi Kuang, Haoyue Lan, Andrew Pickering, D. Marc Rosen, Susan L. Dalrymple, Brian W. Simons, Nitin Joshi, Oren Levy, Lizamma Antony, and Oliver C. Rogers

Abstract

PRX302 is a highly potent, mutant bacterial pore-forming biologic protoxin engineered for selective activation by PSA, a serine protease expressed by benign and malignant prostate epithelial cells. Although being developed as a local therapy for benign prostatic hyperplasia and localized prostate cancer, PRX302 cannot be administered systemically as a treatment for metastatic disease due to binding to ubiquitously expressed glycosylphosphatidylinositol (GPI)-anchored proteins, which leads to poor accumulation within the tumor microenvironment. To overcome this limitation, poly-lactic-co-glycolic acid (PLGA) microparticles encapsulating the protoxin were developed, which are known to accumulate in the liver, a major site of metastasis for prostate cancer and other solid tumors. A highly sensitive and reproducible sandwich ELISA to quantify PRX302 released from microparticles was developed. Utilizing this assay, PRX302 release from different microparticle formulations was assessed over multiple days. Hemolysis assays documented PSA-dependent pore formation and lytic potential (i.e., function) of the released protoxin. MTT assays demonstrated that conditioned supernatant from PRX302-loaded, but not blank (i.e., unloaded), PLGA microparticles was highly cytotoxic to PC3 and DU145 human prostate cancer cells in the presence of exogenous PSA. Microparticle encapsulation prevented PRX302 from immediately interacting with GPI-anchored proteins as demonstrated in a competition assay, which resulted in an increased therapeutic index and significant antitumor efficacy following a single dose of PRX302-loaded microparticles in a preclinical model of prostate cancer liver metastasis with no obvious toxicity. These results document that PRX302 released from PLGA microparticles demonstrate in vivo antitumor efficacy in a clinically relevant preclinical model of metastatic prostate cancer.

Published

2023

14. The ChorioAnchor: Design and Testing of a Novel Chorioamniotic Anchoring Device to Enable Percutaneous Fetoscopic Surgery

Author

Achu G. Byju, Ashley Diemer, Christine Luk, Michael J. Heffernan, Michael A. Belfort, Brian W. Simons, Chester J. Koh, Balakrishna Haridas, and Jimmy Espinoza

Subjects

Fetal Membranes, Premature Rupture, Embryology, Swine, Fetoscopy, Uterus, Obstetrics and Gynecology, General Medicine, Article, Pregnancy, Pediatrics, Perinatology and Child Health, Humans, Animals, Female, Radiology, Nuclear Medicine and imaging, Rabbits

Abstract

Introduction: Percutaneous fetoscopic surgery is hampered by an increased risk of preterm prelabor rupture of membranes (PPROM). Recent surgical techniques have shown that suturing the chorioamniotic membranes following laparotomy and uterine exteriorization is associated with a lower risk of PPROM compared to percutaneous in utero surgery. This study presents the ChorioAnchor, a novel resorbable device that percutaneously anchors the chorioamniotic membranes to the uterine wall. Methods: Human factors testing and peel tests were used to simulate the worst-case in-use loading conditions, establishing the device strength requirements. Tensile testing was used to measure the time-zero strength of the device. Porcine cadaver testing was used to examine ultrasound visibility and acute handling characteristics. Short-term host response was examined through an acute 7-day implantation study in a rabbit model. Results: With a time-zero tensile strength of 47 N, the ChorioAnchor exceeded the established 4 N strength requirement. Both the ChorioAnchor and delivery device were seen to be clearly visible under ultrasound imaging. Short-term host response to the device was well within the range expected for this type of device. Conclusion: The ChorioAnchor meets its engineering requirements in the early stages of implantation. Future studies will examine the kinetics of degradation of the device in vitro and in vivo.

Published

2022

15. Supplementary Materials and Methods from Asporin Restricts Mesenchymal Stromal Cell Differentiation, Alters the Tumor Microenvironment, and Drives Metastatic Progression

Author

Paula J. Hurley, Ben H. Park, W. Nathaniel Brennen, John T. Isaacs, Elana J. Fertig, Isla P. Garraway, Daniel L.J. Thorek, Ryan C. Riddle, Steven S. An, Elai Davicioni, Jessie Huang, Tamara Lotan, Michael C. Haffner, Debebe Theodros, Samantha Torquato, Valentina Kugler, Rebecca Miller, Hamda Khan, Brian W. Simons, and Robert M. Hughes

Abstract

Supplementary Materials and Methods

Published

2023

16. Supplementary Table S1 from Germline Variants in Asporin Vary by Race, Modulate the Tumor Microenvironment, and Are Differentially Associated with Metastatic Prostate Cancer

Author

Edward M. Schaeffer, Ashley E. Ross, Luigi Marchionni, William B. Isaacs, Ben H. Park, Steven S. An, Jessie Huang, Lorelei A. Mucci, Kristina M. Jordahl, Jennifer R. Rider, David M. Berman, Sarah D. Isaacs, Charles Ewing, Guifang Yan, R. Jeffrey Karnes, Elai Davicioni, Nicholas Erho, Ismael A. Vergara, George J. Netto, Sheila F. Faraj, Benjamin Benzon, Rebecca M. Miller, Robert M. Hughes, Brian W. Simons, Brian Shinder, Debasish Sundi, and Paula J. Hurley

Abstract

Frequency of germline ASPN D-repeat-length in JHH prostate cancer cases and controls.

Published

2023

17. Supplementary Tables S2-4 from Germline Variants in Asporin Vary by Race, Modulate the Tumor Microenvironment, and Are Differentially Associated with Metastatic Prostate Cancer

Author

Edward M. Schaeffer, Ashley E. Ross, Luigi Marchionni, William B. Isaacs, Ben H. Park, Steven S. An, Jessie Huang, Lorelei A. Mucci, Kristina M. Jordahl, Jennifer R. Rider, David M. Berman, Sarah D. Isaacs, Charles Ewing, Guifang Yan, R. Jeffrey Karnes, Elai Davicioni, Nicholas Erho, Ismael A. Vergara, George J. Netto, Sheila F. Faraj, Benjamin Benzon, Rebecca M. Miller, Robert M. Hughes, Brian W. Simons, Brian Shinder, Debasish Sundi, and Paula J. Hurley

Abstract

Supplementary Table S2 shows bivariate and multivariable analyses of germline ASPN D13/14 compared to ASPN D13/13 for lymph node involvement and metastatic recurrence. Supplementary Table S3 show bivariate analyses of ASPN D genotypes/alleles for biochemical recurrence. Supplementary Table S4 shows multivariable analyses of ASPN D13/14 for biochemical recurrence.

Published

2023

18. Supplemental Figures from TWIST1-WDR5-Hottip Regulates Hoxa9 Chromatin to Facilitate Prostate Cancer Metastasis

Author

Phuoc T. Tran, Colm Morrissey, Paula J. Hurley, Kenneth J. Pienta, Edward M. Schaeffer, Ashley E. Ross, Theodore L. DeWeese, Steven S. An, Lawrence True, Arum R. Yoon, Ghali Lemtiri-Chlieh, Kekoa Taparra, Hailun Wang, Katriana Nugent, Brian W. Simons, Belinda Nghiem, Russell D. Williams, Rajendra P. Gajula, and Reem Malek

Abstract

This document contains supplemental details such as antibodies and primers, list of genes overrepresented in TWIST1 and TWIST1 mutants, IHC staining for TWIST1 in mouse prostate development, IHC staining for TWIST1 and HOXA9 in various mouse models of prostate cancer, correlation of TWIST1 and HOXA9 alteration with poor survival in human prostate cancer patients, IHC for TWIST1 and HOXA9 on primary tumors and bone metastasis from prostate cancer patients, IHC for HOXA9 on cell pellets expressing HOXA9 or control and on adult mouse prostate, data showing sufficiency of HOXA9 for some pro-metastatic behaviour in prostate cancer cells, data showing requirement of WDR5 and HOTTIP for TWIST1-dependent pro-metastatic behavior, ChIP data showing binding of TWIST1 and HOXA9 at the HOXA9 promoter, data showing effect of drugs that can inhibit HOXA9 on prostate cancer cell viability and pro metastatic behaviour.

Published

2023

19. Supplementary Figure S1 from Germline Variants in Asporin Vary by Race, Modulate the Tumor Microenvironment, and Are Differentially Associated with Metastatic Prostate Cancer

Author

Edward M. Schaeffer, Ashley E. Ross, Luigi Marchionni, William B. Isaacs, Ben H. Park, Steven S. An, Jessie Huang, Lorelei A. Mucci, Kristina M. Jordahl, Jennifer R. Rider, David M. Berman, Sarah D. Isaacs, Charles Ewing, Guifang Yan, R. Jeffrey Karnes, Elai Davicioni, Nicholas Erho, Ismael A. Vergara, George J. Netto, Sheila F. Faraj, Benjamin Benzon, Rebecca M. Miller, Robert M. Hughes, Brian W. Simons, Brian Shinder, Debasish Sundi, and Paula J. Hurley

Abstract

ASPN antibody validation.

Published

2023

20. Supplementary Data from Asporin Restricts Mesenchymal Stromal Cell Differentiation, Alters the Tumor Microenvironment, and Drives Metastatic Progression

Author

Paula J. Hurley, Ben H. Park, W. Nathaniel Brennen, John T. Isaacs, Elana J. Fertig, Isla P. Garraway, Daniel L.J. Thorek, Ryan C. Riddle, Steven S. An, Elai Davicioni, Jessie Huang, Tamara Lotan, Michael C. Haffner, Debebe Theodros, Samantha Torquato, Valentina Kugler, Rebecca Miller, Hamda Khan, Brian W. Simons, and Robert M. Hughes

Abstract

Figure S1: Comparison of Aspn+/+ and Aspn-/- mice. Figure S2: Representative gating of murine MSCs. Figure S3: ASPN restricts MSC differentiation. Figure S4: ASPN expression in cancer cell lines. Figure S5: ASPN increases cancer cell migration. Figure S6: ASPN expression in B6CaP allografts and organoids.

Published

2023

21. Data from Asporin Restricts Mesenchymal Stromal Cell Differentiation, Alters the Tumor Microenvironment, and Drives Metastatic Progression

Author

Paula J. Hurley, Ben H. Park, W. Nathaniel Brennen, John T. Isaacs, Elana J. Fertig, Isla P. Garraway, Daniel L.J. Thorek, Ryan C. Riddle, Steven S. An, Elai Davicioni, Jessie Huang, Tamara Lotan, Michael C. Haffner, Debebe Theodros, Samantha Torquato, Valentina Kugler, Rebecca Miller, Hamda Khan, Brian W. Simons, and Robert M. Hughes

Abstract

Tumor progression to metastasis is not cancer cell autonomous, but rather involves the interplay of multiple cell types within the tumor microenvironment. Here we identify asporin (ASPN) as a novel, secreted mesenchymal stromal cell (MSC) factor in the tumor microenvironment that regulates metastatic development. MSCs expressed high levels of ASPN, which decreased following lineage differentiation. ASPN loss impaired MSC self-renewal and promoted terminal cell differentiation. Mechanistically, secreted ASPN bound to BMP-4 and restricted BMP-4–induced MSC differentiation prior to lineage commitment. ASPN expression was distinctly conserved between MSC and cancer-associated fibroblasts (CAF). ASPN expression in the tumor microenvironment broadly impacted multiple cell types. Prostate tumor allografts in ASPN-null mice had a reduced number of tumor-associated MSCs, fewer cancer stem cells, decreased tumor vasculature, and an increased percentage of infiltrating CD8+ T cells. ASPN-null mice also demonstrated a significant reduction in lung metastases compared with wild-type mice. These data establish a role for ASPN as a critical MSC factor that extensively affects the tumor microenvironment and induces metastatic progression.Significance:These findings show that asporin regulates key properties of mesenchymal stromal cells, including self-renewal and multipotency, and asporin expression by reactive stromal cells alters the tumor microenvironment and promotes metastatic progression.

Published

2023

22. Data from TWIST1-WDR5-Hottip Regulates Hoxa9 Chromatin to Facilitate Prostate Cancer Metastasis

Author

Phuoc T. Tran, Colm Morrissey, Paula J. Hurley, Kenneth J. Pienta, Edward M. Schaeffer, Ashley E. Ross, Theodore L. DeWeese, Steven S. An, Lawrence True, Arum R. Yoon, Ghali Lemtiri-Chlieh, Kekoa Taparra, Hailun Wang, Katriana Nugent, Brian W. Simons, Belinda Nghiem, Russell D. Williams, Rajendra P. Gajula, and Reem Malek

Abstract

TWIST1 is a transcription factor critical for development that can promote prostate cancer metastasis. During embryonic development, TWIST1 and HOXA9 are coexpressed in mouse prostate and then silenced postnatally. Here we report that TWIST1 and HOXA9 coexpression are reactivated in mouse and human primary prostate tumors and are further enriched in human metastases, correlating with survival. TWIST1 formed a complex with WDR5 and the lncRNA Hottip/HOTTIP, members of the MLL/COMPASS–like H3K4 methylases, which regulate chromatin in the Hox/HOX cluster during development. TWIST1 overexpression led to coenrichment of TWIST1 and WDR5 as well as increased H3K4me3 chromatin at the Hoxa9/HOXA9 promoter, which was dependent on WDR5. Expression of WDR5 and Hottip/HOTTIP was also required for TWIST1-induced upregulation of HOXA9 and aggressive cellular phenotypes such as invasion and migration. Pharmacologic inhibition of HOXA9 prevented TWIST1-induced aggressive prostate cancer cellular phenotypes in vitro and metastasis in vivo. This study demonstrates a novel mechanism by which TWIST1 regulates chromatin and gene expression by cooperating with the COMPASS-like complex to increase H3K4 trimethylation at target gene promoters. Our findings highlight a TWIST1–HOXA9 embryonic prostate developmental program that is reactivated during prostate cancer metastasis and is therapeutically targetable. Cancer Res; 77(12); 3181–93. ©2017 AACR.

Published

2023

23. Supplementary Materials and Methods from TWIST1-WDR5-Hottip Regulates Hoxa9 Chromatin to Facilitate Prostate Cancer Metastasis

Author

Phuoc T. Tran, Colm Morrissey, Paula J. Hurley, Kenneth J. Pienta, Edward M. Schaeffer, Ashley E. Ross, Theodore L. DeWeese, Steven S. An, Lawrence True, Arum R. Yoon, Ghali Lemtiri-Chlieh, Kekoa Taparra, Hailun Wang, Katriana Nugent, Brian W. Simons, Belinda Nghiem, Russell D. Williams, Rajendra P. Gajula, and Reem Malek

Abstract

This document contains experimental details for microarray data acquisition and analysis, immunohistochemistry, immunofluorescence, western blotting, migration assay, invasion assay, anoikis assay, soft agar colony formation assay, RNA-immunoprecipitation, protein co-immunoprecipitation, Chromatin immunoprecipitation (ChIP), ChIP-Re-ChIP.

Published

2023

24. Supplementary Tables S6 and S7 from Germline Variants in Asporin Vary by Race, Modulate the Tumor Microenvironment, and Are Differentially Associated with Metastatic Prostate Cancer

Author

Edward M. Schaeffer, Ashley E. Ross, Luigi Marchionni, William B. Isaacs, Ben H. Park, Steven S. An, Jessie Huang, Lorelei A. Mucci, Kristina M. Jordahl, Jennifer R. Rider, David M. Berman, Sarah D. Isaacs, Charles Ewing, Guifang Yan, R. Jeffrey Karnes, Elai Davicioni, Nicholas Erho, Ismael A. Vergara, George J. Netto, Sheila F. Faraj, Benjamin Benzon, Rebecca M. Miller, Robert M. Hughes, Brian W. Simons, Brian Shinder, Debasish Sundi, and Paula J. Hurley

Abstract

Supplementary Tables S6 shows bivariate analyses of the most common germline ASPN D genotypes/alleles for adverse pathology. Supplementary Table S7 shows multivariable analyses of ASPN D13/14 and Any 14 with lymph node involvement.

Published

2023

25. Supplementary Figure 7 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 7894K, Supplementary Figure 7. Xenograft models of aggressive prostate cancer.

Published

2023

26. Supplementary Figure S6. SPARCL1 engages cell-ECM interactions. from Androgen-Regulated SPARCL1 in the Tumor Microenvironment Inhibits Metastatic Progression

Author

Edward M. Schaeffer, Steven S. An, Srinivasan Yegnasubramanian, George J. Netto, Elai Davicioni, Sheila F. Faraj, Ismael A. Vergara, Nicholas Erho, Ashley E. Ross, Javaneh Jabbari, Yasunori Kimura, David Esopi, Michael C. Haffner, Brian Shinder, Rebecca M. Miller, Jessie Huang, Brian W. Simons, Robert M. Hughes, and Paula J. Hurley

Abstract

Supplementary Figure S6

Published

2023

27. Supplementary Figure S4. SPARCL1 inhibits cytoskeletal remodeling. from Androgen-Regulated SPARCL1 in the Tumor Microenvironment Inhibits Metastatic Progression

Author

Edward M. Schaeffer, Steven S. An, Srinivasan Yegnasubramanian, George J. Netto, Elai Davicioni, Sheila F. Faraj, Ismael A. Vergara, Nicholas Erho, Ashley E. Ross, Javaneh Jabbari, Yasunori Kimura, David Esopi, Michael C. Haffner, Brian Shinder, Rebecca M. Miller, Jessie Huang, Brian W. Simons, Robert M. Hughes, and Paula J. Hurley

Abstract

Supplementary Figure S4

Published

2023

28. Supplementary Figure 6 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 3402K, Supplementary Figure 6. Additional PTEN/AKT Pathway models.

Published

2023

29. Supplementary Figure S5. SPARCL-1 coated beads do not reinforce cellular traction. from Androgen-Regulated SPARCL1 in the Tumor Microenvironment Inhibits Metastatic Progression

Author

Edward M. Schaeffer, Steven S. An, Srinivasan Yegnasubramanian, George J. Netto, Elai Davicioni, Sheila F. Faraj, Ismael A. Vergara, Nicholas Erho, Ashley E. Ross, Javaneh Jabbari, Yasunori Kimura, David Esopi, Michael C. Haffner, Brian Shinder, Rebecca M. Miller, Jessie Huang, Brian W. Simons, Robert M. Hughes, and Paula J. Hurley

Abstract

Supplementary Figure S5

Published

2023

30. Supplementary Figure Legend from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 60K

Published

2023

31. Supplementary Materials and Methods and Supplementary Figure Legends from Androgen-Regulated SPARCL1 in the Tumor Microenvironment Inhibits Metastatic Progression

Author

Edward M. Schaeffer, Steven S. An, Srinivasan Yegnasubramanian, George J. Netto, Elai Davicioni, Sheila F. Faraj, Ismael A. Vergara, Nicholas Erho, Ashley E. Ross, Javaneh Jabbari, Yasunori Kimura, David Esopi, Michael C. Haffner, Brian Shinder, Rebecca M. Miller, Jessie Huang, Brian W. Simons, Robert M. Hughes, and Paula J. Hurley

Abstract

This file consists of the Supplementary Materials and Methods and the Supplementary Figure Legends.

Published

2023

32. Supplementary Figure 1 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 9226K, Supplementary Figure 1. Differentiating primary and metastatic lung lesions in GEM mouse models.

Published

2023

33. Supplementary Figure 4 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 17933K, Supplementary Figure 4. Neuroendocrine carcinoma.

Published

2023

34. Supplementary Figure 3 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 2509K, Supplementary Figure 3. Heterologous differentiation in prostate.

Published

2023

35. Supplementary Figure S2. AR directly represses SPARCL1 expression in prostate cancer. from Androgen-Regulated SPARCL1 in the Tumor Microenvironment Inhibits Metastatic Progression

Author

Edward M. Schaeffer, Steven S. An, Srinivasan Yegnasubramanian, George J. Netto, Elai Davicioni, Sheila F. Faraj, Ismael A. Vergara, Nicholas Erho, Ashley E. Ross, Javaneh Jabbari, Yasunori Kimura, David Esopi, Michael C. Haffner, Brian Shinder, Rebecca M. Miller, Jessie Huang, Brian W. Simons, Robert M. Hughes, and Paula J. Hurley

Abstract

Supplementary Figure S2

Published

2023

36. Supplementary Figure 2 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 2674K, Supplementary Figure 2. Lung metastasis versus tumor embolism.

Published

2023

37. Supplementary Figure S1. Androgen suppresses SPARCL1 expression. from Androgen-Regulated SPARCL1 in the Tumor Microenvironment Inhibits Metastatic Progression

Author

Edward M. Schaeffer, Steven S. An, Srinivasan Yegnasubramanian, George J. Netto, Elai Davicioni, Sheila F. Faraj, Ismael A. Vergara, Nicholas Erho, Ashley E. Ross, Javaneh Jabbari, Yasunori Kimura, David Esopi, Michael C. Haffner, Brian Shinder, Rebecca M. Miller, Jessie Huang, Brian W. Simons, Robert M. Hughes, and Paula J. Hurley

Abstract

Supplementary Figure S1

Published

2023

38. Supplementary Figure 5 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 4441K, Supplementary Figure 5. PTEN/AKT Pathway models.

Published

2023

39. Supplementary Figure S3. The tumor microenvironment in Sparcl1-/- models. from Androgen-Regulated SPARCL1 in the Tumor Microenvironment Inhibits Metastatic Progression

Author

Edward M. Schaeffer, Steven S. An, Srinivasan Yegnasubramanian, George J. Netto, Elai Davicioni, Sheila F. Faraj, Ismael A. Vergara, Nicholas Erho, Ashley E. Ross, Javaneh Jabbari, Yasunori Kimura, David Esopi, Michael C. Haffner, Brian Shinder, Rebecca M. Miller, Jessie Huang, Brian W. Simons, Robert M. Hughes, and Paula J. Hurley

Abstract

Supplementary Figure S3

Published

2023

40. Supplementary Figure S7. Responses to SPARCL1-coated beads are concentration dependent. from Androgen-Regulated SPARCL1 in the Tumor Microenvironment Inhibits Metastatic Progression

Author

Edward M. Schaeffer, Steven S. An, Srinivasan Yegnasubramanian, George J. Netto, Elai Davicioni, Sheila F. Faraj, Ismael A. Vergara, Nicholas Erho, Ashley E. Ross, Javaneh Jabbari, Yasunori Kimura, David Esopi, Michael C. Haffner, Brian Shinder, Rebecca M. Miller, Jessie Huang, Brian W. Simons, Robert M. Hughes, and Paula J. Hurley

Abstract

Supplementary Figure S7

Published

2023

41. Supplementary Table 1 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 38K

Published

2023

42. Supplementary Table 2 from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

PDF file - 24K

Published

2023

43. Data from Androgen-Regulated SPARCL1 in the Tumor Microenvironment Inhibits Metastatic Progression

Author

Edward M. Schaeffer, Steven S. An, Srinivasan Yegnasubramanian, George J. Netto, Elai Davicioni, Sheila F. Faraj, Ismael A. Vergara, Nicholas Erho, Ashley E. Ross, Javaneh Jabbari, Yasunori Kimura, David Esopi, Michael C. Haffner, Brian Shinder, Rebecca M. Miller, Jessie Huang, Brian W. Simons, Robert M. Hughes, and Paula J. Hurley

Abstract

Prostate cancer is a leading cause of cancer death in men due to the subset of cancers that progress to metastasis. Prostate cancers are thought to be hardwired to androgen receptor (AR) signaling, but AR-regulated changes in the prostate that facilitate metastasis remain poorly understood. We previously noted a marked reduction in secreted protein, acidic and rich in cysteine-like 1 (SPARCL1) expression during invasive phases of androgen-induced prostate growth, suggesting that this may be a novel invasive program governed by AR. Herein, we show that SPARCL1 loss occurs concurrently with AR amplification or overexpression in patient-based data. Mechanistically, we demonstrate that SPARCL1 expression is directly suppressed by androgen-induced AR activation and binding at the SPARCL1 locus via an epigenetic mechanism, and these events can be pharmacologically attenuated with either AR antagonists or HDAC inhibitors. We establish using the Hi-Myc model of prostate cancer that in Hi-Myc/Sparcl1−/− mice, SPARCL1 functions to suppress cancer formation. Moreover, metastatic progression of Myc-CaP orthotopic allografts is restricted by SPARCL1 in the tumor microenvironment. Specifically, we show that SPARCL1 both tethers to collagen in the extracellular matrix (ECM) and binds to the cell's cytoskeleton. SPARCL1 directly inhibits the assembly of focal adhesions, thereby constraining the transmission of cell traction forces. Our findings establish a new insight into AR-regulated prostate epithelial movement and provide a novel framework whereby SPARCL1 in the ECM microenvironment restricts tumor progression by regulating the initiation of the network of physical forces that may be required for metastatic invasion of prostate cancer. Cancer Res; 75(20); 4322–34. ©2015 AACR.

Published

2023

44. Data from Animal Models of Human Prostate Cancer: The Consensus Report of the New York Meeting of the Mouse Models of Human Cancers Consortium Prostate Pathology Committee

Author

Robert D. Cardiff, Alexander Borowsky, George Thomas, Massimo Loda, Gerald C. Chu, Brian D. Robinson, Jerrold M. Ward, Brian W. Simons, Ruth Sullivan, Sabina Signoretti, Philip Martin, Enrico Radaelli, Jiaoti Huang, and Michael Ittmann

Abstract

Animal models, particularly mouse models, play a central role in the study of the etiology, prevention, and treatment of human prostate cancer. While tissue culture models are extremely useful in understanding the biology of prostate cancer, they cannot recapitulate the complex cellular interactions within the tumor microenvironment that play a key role in cancer initiation and progression. The National Cancer Institute (NCI) Mouse Models of Human Cancers Consortium convened a group of human and veterinary pathologists to review the current animal models of prostate cancer and make recommendations about the pathologic analysis of these models. More than 40 different models with 439 samples were reviewed, including genetically engineered mouse models, xenograft, rat, and canine models. Numerous relevant models have been developed over the past 15 years, and each approach has strengths and weaknesses. Analysis of multiple genetically engineered models has shown that reactive stroma formation is present in all the models developing invasive carcinomas. In addition, numerous models with multiple genetic alterations display aggressive phenotypes characterized by sarcomatoid carcinomas and metastases, which is presumably a histologic manifestation of epithelial–mesenchymal transition. The significant progress in development of improved models of prostate cancer has already accelerated our understanding of the complex biology of prostate cancer and promises to enhance development of new approaches to prevention, detection, and treatment of this common malignancy. Cancer Res; 73(9); 2718–36. ©2013 AACR.

Published

2023

45. Cover Image: Volume 83 Issue 3

Author

Mindy K. Graham, Roshan Chikarmane, Rulin Wang, Ajay Vaghasia, Anuj Gupta, Qizhi Zheng, Bulouere Wodu, Xin Pan, Nicole Castagna, Jianyong Liu, Jennifer Meyers, Alyza Skaist, Sarah Wheelan, Brian W. Simons, Charles Bieberich, William G. Nelson, Theodore L. DeWeese, Angelo M. De Marzo, and Srinivasan Yegnasubramanian

Subjects

Oncology, Urology

Published

2023

46. Blind Image Restoration Enhances Digital Autoradiographic Imaging of Radiopharmaceutical Tissue Distribution

Author

Russell K. Pachynski, Brian W. Simons, Wen Jiang, Nadia Benabdallah, Daniel L.J. Thorek, Peng Lu, Abhinav K. Jha, Hanwen Zhang, Robert F. Hobbs, Brian C. Baumann, and David Ulmert

Subjects

Diagnostic Imaging, Male, Point spread function, Computer science, Noise reduction, Image processing, Background noise, Mice, Contrast-to-noise ratio, Fluorodeoxyglucose F18, Image Processing, Computer-Assisted, Animals, Humans, Tissue Distribution, Radiology, Nuclear Medicine and imaging, Image resolution, Image restoration, Phantoms, Imaging, business.industry, Pattern recognition, Radionuclide therapy, Autoradiography, Artificial intelligence, Radiopharmaceuticals, business, Algorithms

Abstract

Digital autoradiography (DAR) is a powerful tool to quantitatively determine the distribution of a radiopharmaceutical within a tissue section and is widely used in drug discovery and development. However, the low image resolution and significant background noise can result in poor correlation, even errors, between radiotracer distribution, anatomical structure, and molecular expression profiles. Differing from conventional optical systems, the point spread function (PSF) in DAR is determined by properties of radioisotope decay, phosphor and digitizer. Calibration of an experimental PSF a priori is difficult, prone to error, and impractical. We have developed a content-adaptive restoration algorithm to address these problems. Methods: We model the DAR imaging process using a mixed Poisson-Gaussian model, and blindly restore the image by a Penalized Maximum-Likelihood Expectation-Maximization algorithm (PG- PEM). PG-PEM implements a patch-based estimation algorithm with "Density-Based Spatial Clus- tering of Applications with Noise" to estimate noise parameters, and utilizes L2 and Hessian Frobenius (HF) norms as regularization functions to improve performance. Results: First, PG-PEM outperformed other restoration algorithms at the denoising task (p

Published

2021

47. Improved 223Ra Therapy with Combination Epithelial Sodium Channel Blockade

Author

Mark S. Longtine, Ryan C. Riddle, David Ulmert, Lucy Summer, Jeff M. Michalski, Brian W. Simons, Amanda Fears, Nadia Benabdallah, Nicholas C. Zachos, Denise Chesner, Diane Abou, Michele Doucet, Daniel L.J. Thorek, and Richard L. Wahl

Subjects

Epithelial sodium channel, Radium-223, business.industry, Cancer, Pharmacology, medicine.disease, Bone remodeling, Amiloride, Prostate cancer, In vivo, Radionuclide therapy, Medicine, Radiology, Nuclear Medicine and imaging, business, medicine.drug

Abstract

Background: Radium-223 dichloride ([223Ra]RaCl2) is the first approved alpha particle-emitting therapy and is indicated for treatment of bone metastatic castrate resistant prostate cancer. Approximately half of the dose is absorbed into the gastrointestinal (GI) tract within minutes of administration, limiting disease-site uptake and contributing to toxicity. Here, we investigate the role of enteric ion channels and their modulation for improved therapeutic efficacy and reduced side effects. Methods: Utilizing primary human duodenal organoids (enteroids) as in vitro models of the functional GI epithelium, we found that Amiloride (ENaC blocker) and NS-1619 (K+ channel activator) presented significant effects in 223Ra membranal transport. The radioactive drug distribution was evaluated for lead combinations in vivo, and in osteosarcoma and prostate cancer models. Results: Amiloride shifted 223Ra uptake in vivo from the gut, to nearly double the uptake at sites of bone remodeling. Bone tumor growth inhibition with the combination as measured by bioluminescent and X-ray imaging was significantly greater than single agents alone, and the combination resulted in no weight loss. Conclusion: This combination of approved agents may be readily implemented as a clinical approach to improve outcomes of bone metastatic cancer patients with the benefit of ameliorated tolerability.

Published

2021

48. Stromal CAVIN1 Controls Prostate Cancer Microenvironment and Metastasis by Modulating Lipid Distribution and Inflammatory Signaling

Author

Jin Yih Low, W. Nathaniel Brennen, Alan K. Meeker, Brian W. Simons, Elina Ikonen, and Marikki Laiho

Subjects

Male, 0301 basic medicine, Cancer Research, Stromal cell, Inflammation, medicine.disease_cause, Article, Metastasis, 03 medical and health sciences, Prostate cancer, 0302 clinical medicine, Caveolae, Tumor Microenvironment, medicine, Humans, Neoplasm Metastasis, Molecular Biology, Tumor microenvironment, Chemistry, Prostatic Neoplasms, RNA-Binding Proteins, Lipid metabolism, Lipid Metabolism, medicine.disease, 030104 developmental biology, Oncology, 030220 oncology & carcinogenesis, Cancer research, medicine.symptom, Carcinogenesis, Signal Transduction

Abstract

Lipid uptake occurs through caveolae, plasma membrane invaginations formed by caveolins (CAV) and caveolae-associated protein 1 (CAVIN1). Genetic alterations of CAV1N1 and CAV1 modify lipid metabolism and underpin lipodystrophy syndromes. Lipids contribute to tumorigenesis by providing fuel to cancer metabolism and supporting growth and signaling. Tumor stroma promotes tumor proliferation, invasion, and metastasis, but how stromal lipids influence these processes remain to be defined. Here, we show that stromal CAVIN1 regulates lipid abundance in the prostate cancer microenvironment and suppresses metastasis. We show that depletion of CAVIN1 in prostate stromal cells markedly reduces their lipid droplet accumulation and increases inflammation. Stromal cells lacking CAVIN1 enhance prostate cancer cell migration and invasion. Remarkably, they increase lipid uptake and M2 inflammatory macrophage infiltration in the primary tumors and metastasis to distant sites. Our data support the concept that stromal cells contribute to prostate cancer aggressiveness by modulating lipid content and inflammation in the tumor microenvironment. Implications: This study showed that stromal CAVIN1 suppresses prostate cancer metastasis by modulating tumor microenvironment, lipid content, and inflammatory response.

Published

2020

49. Preclinical Single Photon Emission Computed Tomography of Alpha Particle-Emitting Radium-223

Author

Diane Abou, Daniel L.J. Thorek, Andrew Rittenbach, Paige Finley, Benjamin M. W. Tsui, Ryan C. Riddle, David Ulmert, Ryan E. Tomlinson, Brian W. Simons, and Abhinav K. Jha

Subjects

Male, 0301 basic medicine, Radium-223, Cancer Research, Materials science, Photon, Bone Neoplasms, Single-photon emission computed tomography, Bone and Bones, Imaging phantom, law.invention, Mice, 03 medical and health sciences, 0302 clinical medicine, law, medicine, Animals, Humans, Tissue Distribution, Radiology, Nuclear Medicine and imaging, Radioisotopes, Tomography, Emission-Computed, Single-Photon, Pharmacology, medicine.diagnostic_test, Phantoms, Imaging, Collimator, Original Articles, General Medicine, Alpha particle, Prostatic Neoplasms, Castration-Resistant, 030104 developmental biology, Oncology, 030220 oncology & carcinogenesis, Models, Animal, Autoradiography, Radiopharmaceuticals, Molecular imaging, α particles, Radium, medicine.drug, Biomedical engineering

Abstract

Objective: Dose optimization and pharmacokinetic evaluation of α-particle emitting radium-223 dichloride ((223)RaCl(2)) by planar γ-camera or single photon emission computed tomography (SPECT) imaging are hampered by the low photon abundance and injected activities. In this study, we demonstrate SPECT of (223)Ra using phantoms and small animal in vivo models. Methods: Line phantoms and mice bearing (223)Ra were imaged using a dedicated small animal SPECT by detecting the low-energy photon emissions from (223)Ra. Localization of the therapeutic agent was verified by whole-body and whole-limb autoradiography and its radiobiological effect confirmed by immunofluorescence. Results: A state-of-the-art commercial small animal SPECT system equipped with a highly sensitive collimator enables collection of sufficient counts for three-dimensional reconstruction at reasonable administered activities and acquisition times. Line sources of (223)Ra in both air and in a water scattering phantom gave a line spread function with a full-width-at-half-maximum of 1.45 mm. Early and late-phase imaging of the pharmacokinetics of the radiopharmaceutical were captured. Uptake at sites of active bone remodeling was correlated with DNA damage from the α particle emissions. Conclusions: This work demonstrates the capability to noninvasively define the distribution of (223)RaCl(2), a recently approved α-particle-emitting radionuclide. This approach allows quantitative assessment of (223)Ra distribution and may assist radiation-dose optimization strategies to improve therapeutic response and ultimately to enable personalized treatment planning.

Published

2020

50. Single-cell atlas of epithelial and stromal cell heterogeneity by lobe and strain in the mouse prostate

Author

Mindy K Graham, Roshan Chikarmane, Rulin Wang, Ajay Vaghasia, Anuj Gupta, Qizhi Zheng, Bulouere Wodu, Xin Pan, Nicole Castagna, Jianyong Liu, Jennifer Meyers, Alyza Skaist, Sarah Wheelan, Brian W Simons, Charles Bieberich, William G Nelson, Theodore L DeWeese, Angelo M De Marzo, and Srinivasan Yegnasubramanian

Subjects

History, Oncology, Polymers and Plastics, Urology, Business and International Management, Industrial and Manufacturing Engineering

Abstract

Evaluating the complex interplay of cell types in the tissue microenvironment is critical to understanding the origin and progression of diseases in the prostate and potential opportunities for intervention. Mouse models are an essential tool to investigate the molecular and cell-type-specific contributions of prostate disease at an organismal level. While there are well-documented differences in the extent, timing, and nature of disease development in various genetically engineered and exposure-based mouse models in different mouse strains and prostate lobes within each mouse strain, the underlying molecular phenotypic differences in cell types across mouse strains and prostate lobes are incompletely understood.In this study, we used single-cell RNA-sequencing (scRNA-seq) methods to assess the single-cell transcriptomes of 6-month-old mouse prostates from two commonly used mouse strains, friend virus B/NIH jackson (FVB/NJ) (N = 2) and C57BL/6J (N = 3). For each mouse, the lobes of the prostate were dissected (anterior, dorsal, lateral, and ventral), and individual scRNA-seq libraries were generated. In situ and pathological analyses were used to explore the spatial and anatomical distributions of novel cell types and molecular markers defining these cell types.Data dimensionality reduction and clustering analysis of scRNA-seq data revealed that basal and luminal cells possessed strain-specific transcriptomic differences, with luminal cells also displaying marked lobe-specific differences. Gene set enrichment analysis comparing luminal cells by strain showed enrichment of proto-Oncogene targets in FVB/NJ mice. Additionally, three rare populations of epithelial cells clustered independently of strain and lobe: one population of luminal cells expressing Foxi1 and components of the vacuolar ATPase proton pump (Atp6v0d2 and Atp6v1g3), another population expressing Psca and other stem cell-associated genes (Ly6a/Sca-1, Tacstd2/Trop-2), and a neuroendocrine population expressing Chga, Chgb, and Syp. In contrast, stromal cell clusters, including fibroblasts, smooth muscle cells, endothelial cells, pericytes, and immune cell types, were conserved across strain and lobe, clustering largely by cell type and not by strain or lobe. One notable exception to this was the identification of two distinct fibroblast populations that we term subglandular fibroblasts and interstitial fibroblasts based on their strikingly distinct spatial distribution in the mouse prostate.Altogether, these data provide a practical reference of the transcriptional profiles of mouse prostate from two commonly used mouse strains and across all four prostate lobes.

Published

2022