Literature DB >> 33293372

Molecular Imaging of Prostate Cancer Targeting CD46 Using ImmunoPET.

Sinan Wang1, Jun Li2,3, Jun Hua2,4, Yang Su5, Denis R Beckford-Vera1, Walter Zhao1, Mayuri Jayaraman1, Tony L Huynh1, Ning Zhao1, Yung-Hua Wang1, Yangjie Huang1, Fujun Qin6, Sui Shen7, Daniel Gioeli8,9, Robert Dreicer9,10, Renuka Sriram1, Emily A Egusa11,12, Jonathan Chou11,12, Felix Y Feng11,12, Rahul Aggarwal11,13, Michael J Evans1,11,14, Youngho Seo1,11,12, Bin Liu15,11, Robert R Flavell16,11,14, Jiang He17,9.   

Abstract

PURPOSE: We recently identified CD46 as a novel therapeutic target in prostate cancer. In this study, we developed a CD46-targeted PET radiopharmaceutical, [89Zr]DFO-YS5, and evaluated its performance for immunoPET imaging in murine prostate cancer models. EXPERIMENTAL
DESIGN: [89Zr]DFO-YS5 was prepared and its in vitro binding affinity for CD46 was measured. ImmunoPET imaging was conducted in male athymic nu/nu mice bearing DU145 [AR-, CD46+, prostate-specific membrane antigen-negative (PSMA-)] or 22Rv1 (AR+, CD46+, PSMA+) tumors, and in NOD/SCID gamma mice bearing patient-derived adenocarcinoma xenograft, LTL-331, and neuroendocrine prostate cancers, LTL-331R and LTL-545.
RESULTS: [89Zr]DFO-YS5 binds specifically to the CD46-positive human prostate cancer DU145 and 22Rv1 xenografts. In biodistribution studies, the tumor uptake of [89Zr]DFO-YS5 was 13.3 ± 3.9 and 11.2 ± 2.5 %ID/g, respectively, in DU145 and 22Rv1 xenografts, 4 days postinjection. Notably, [89Zr]DFO-YS5 demonstrated specific uptake in the PSMA- and AR-negative DU145 model. [89Zr]DFO-YS5 also showed uptake in the patient-derived LTL-331 and -331R models, with particularly high uptake in the LTL-545 neuroendocrine prostate cancer tumors (18.8 ± 5.3, 12.5 ± 1.8, and 32 ± 5.3 %ID/g in LTL-331, LTL-331R, and LTL-545, respectively, at 4 days postinjection).
CONCLUSIONS: [89Zr]DFO-YS5 is an excellent PET imaging agent across a panel of prostate cancer models, including in both adenocarcinoma and neuroendocrine prostate cancer, both cell line- and patient-derived xenografts, and both PSMA-positive and -negative tumors. It demonstrates potential for clinical translation as an imaging agent, theranostic platform, and companion biomarker in prostate cancer. ©2020 American Association for Cancer Research.

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Year:  2020        PMID: 33293372      PMCID: PMC7925362          DOI: 10.1158/1078-0432.CCR-20-3310

Source DB:  PubMed          Journal:  Clin Cancer Res        ISSN: 1078-0432            Impact factor:   13.801


  40 in total

1.  225Ac-PSMA-617 for PSMA-Targeted α-Radiation Therapy of Metastatic Castration-Resistant Prostate Cancer.

Authors:  Clemens Kratochwil; Frank Bruchertseifer; Frederik L Giesel; Mirjam Weis; Frederik A Verburg; Felix Mottaghy; Klaus Kopka; Christos Apostolidis; Uwe Haberkorn; Alfred Morgenstern
Journal:  J Nucl Med       Date:  2016-07-07       Impact factor: 10.057

2.  Advances in immuno-positron emission tomography: antibodies for molecular imaging in oncology.

Authors:  Scott M Knowles; Anna M Wu
Journal:  J Clin Oncol       Date:  2012-09-17       Impact factor: 44.544

3.  Quantitative immunoPET of prostate cancer xenografts with 89Zr- and 124I-labeled anti-PSCA A11 minibody.

Authors:  Scott M Knowles; Kirstin A Zettlitz; Richard Tavaré; Matthew M Rochefort; Felix B Salazar; David B Stout; Paul J Yazaki; Robert E Reiter; Anna M Wu
Journal:  J Nucl Med       Date:  2014-02-06       Impact factor: 10.057

4.  A phase I/IIA study of AGS-PSCA for castration-resistant prostate cancer.

Authors:  M J Morris; M A Eisenberger; R Pili; S R Denmeade; D Rathkopf; S F Slovin; J Farrelly; J J Chudow; M Vincent; H I Scher; M A Carducci
Journal:  Ann Oncol       Date:  2012-05-02       Impact factor: 32.976

5.  Exploitation of CD133 for the Targeted Imaging of Lethal Prostate Cancer.

Authors:  Paige M Glumac; Joseph P Gallant; Mariya Shapovalova; Yingming Li; Paari Murugan; Shilpa Gupta; Ilsa M Coleman; Peter S Nelson; Scott M Dehm; Aaron M LeBeau
Journal:  Clin Cancer Res       Date:  2019-11-15       Impact factor: 12.531

6.  Targeting prostate cancer cells in vivo using a rapidly internalizing novel human single-chain antibody fragment.

Authors:  Jiang He; Yong Wang; Jinjin Feng; Xiaodong Zhu; Xiaoli Lan; Arun K Iyer; Niu Zhang; Youngho Seo; Henry F VanBrocklin; Bin Liu
Journal:  J Nucl Med       Date:  2010-02-11       Impact factor: 10.057

7.  89Zr-DFO-J591 for immunoPET of prostate-specific membrane antigen expression in vivo.

Authors:  Jason P Holland; Vadim Divilov; Neil H Bander; Peter M Smith-Jones; Steven M Larson; Jason S Lewis
Journal:  J Nucl Med       Date:  2010-07-21       Impact factor: 10.057

8.  Imaging Patients with Metastatic Castration-Resistant Prostate Cancer Using 89Zr-DFO-MSTP2109A Anti-STEAP1 Antibody.

Authors:  Jorge A Carrasquillo; Bernard M Fine; Neeta Pandit-Taskar; Steven M Larson; Stephen E Fleming; Josef J Fox; Sarah M Cheal; Joseph A O'Donoghue; Shutian Ruan; Govind Ragupathi; Serge K Lyashchenko; John L Humm; Howard I Scher; Mithat Gönen; Simon P Williams; Daniel C Danila; Michael J Morris
Journal:  J Nucl Med       Date:  2019-05-03       Impact factor: 10.057

9.  Engineered measles virus as a novel oncolytic therapy against prostate cancer.

Authors:  Pavlos Msaouel; Ianko D Iankov; Cory Allen; John C Morris; Veronika von Messling; Roberto Cattaneo; Michael Koutsilieris; Stephen J Russell; Evanthia Galanis
Journal:  Prostate       Date:  2009-01-01       Impact factor: 4.104

Review 10.  The Role of Membrane Bound Complement Regulatory Proteins in Tumor Development and Cancer Immunotherapy.

Authors:  Anne Geller; Jun Yan
Journal:  Front Immunol       Date:  2019-05-21       Impact factor: 7.561
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