The goal of this proposal is to develop a novel approach for tumor cells ablation, while leaving healthy cells alive. This approach is based on 123I, a radioactive iodine isotope that emits Auger electrons. Auger electrons have the advantage of dissipating their energy in a very narrow radius, principally confined to only 10 nanometers. Therefore, unlike the more commonly used ?- and ?-emitters, Auger electron emitters inflict cellular DNA damage only at their targeted site, while leaving healthy cells in the immediate vicinity unaffected. We intend to target the DNA of cancer cells by conjugating 123I to inhibitors of the DNA repair enzyme PARP1. In preliminary experiments, we have shown these agents can efficiently transport ionizing radiation into the nuclei of cancer cells, and we have demonstrated that they are particularly useful for the delivery of targeted payloads to brain tumors. This use relies on the expression of PARP1 in brain tumors being far higher than in the healthy surrounding brain tissue. In addition, Auger emitting PARP1 radiopharmaceuticals are also less likely to damage kidney and liver than ?- or ?-emitting radionuclides, because in those organs, the overwhelming amount of activity should be retained outside of the nucleus, where the toxicity of Auger emitters is significantly lower.
The Specific Aims of this proposal are to synthesize a library of radioiodinated PARP1 targeted inhibitors, and to determine which of them will most likely be successful as Auger 123I-labeled radiotherapeutics, based on their bioavailability, metabolic stability, tissue concentrations and residence times. Parallel SPECT imaging experiments will be used to study the whole body biodistribution and cellular PARP1 expression before and after DNA damaging treatment. For the 123I-labeled lead compound, we will determine extensive pharmacodynamic data, both in vitro as well as in vivo. We will perform a dose escalation study, and measure the effects on tumor growth and systemic toxicity. Infiltrative mouse models will be used to determine the potential impact of this novel radiotherapeutic drug. We will further design combination treatment studies with PARP1 Auger emitters, where sub-therapeutic doses of external beam radiation are used to increase activity and DNA proximity of PARP1, and therapeutic doses are used to increase overall PARP1 expression, with both effects increasing the sensitivity of tumor tissue to the radiotherapeutics. The ultimate goal of this study is to validate PARP1 targeted shuttles for Auger emitters in mouse models of glioblastoma. For this application, an interdisciplinary team of experts has been brought together to aid in the development of this technology. The research team will include Dr. Thomas Reiner (Radiochemistry and Probe Development), Dr. Wolfgang Weber (Nuclear Therapy), Dr. Ronald Blasberg (Neurology) and Dr. John Humm (Medical Physics). Together, the investigators form an ideal team to pursue this novel research avenue, bringing together expertise from a wide variety of disciplines. If successful, the generated data will form the foundation for a future clinical trial at MSK, directly impacting patient care and treatment of glioblastoma.

Public Health Relevance

This project seeks to develop targeted small molecules for a DNA repair enzyme, which will be labeled with a radiotherapeutic iodine isotope that emits Auger electrons, a form of radioactive decay that is confined to very small spaces. In preliminary experiments, we have shown that we can shuttle the therapeutic isotope extremely close to the DNA of glioblastoma cells, causing these cells to be killed, and, importantly, sparing the healthy surrounding tissues. We will use this agent as a single agent chemotherapy, but also in combination with external beam radiation, which will can help transport more Auger Electrons directly to the DNA, where they will inflict the greatest damage. 1

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA204441-05
Application #
9961531
Study Section
Clinical Molecular Imaging and Probe Development (CMIP)
Program Officer
Capala, Jacek
Project Start
2016-07-01
Project End
2021-06-30
Budget Start
2020-07-01
Budget End
2021-06-30
Support Year
5
Fiscal Year
2020
Total Cost
Indirect Cost
Name
Sloan-Kettering Institute for Cancer Research
Department
Type
DUNS #
064931884
City
New York
State
NY
Country
United States
Zip Code
10065
Srimathveeravalli, Govindarajan; Abdel-Atti, Dalya; Pérez-Medina, Carlos et al. (2018) Reversible Electroporation-Mediated Liposomal Doxorubicin Delivery to Tumors Can Be Monitored With 89Zr-Labeled Reporter Nanoparticles. Mol Imaging 17:1536012117749726
Jannetti, Stephen A; Carlucci, Giuseppe; Carney, Brandon et al. (2018) PARP-1-Targeted Radiotherapy in Mouse Models of Glioblastoma. J Nucl Med 59:1225-1233
Brand, Christian; Sadique, Ahmad; Houghton, Jacob L et al. (2018) Leveraging PET to image folate receptor ? therapy of an antibody-drug conjugate. EJNMMI Res 8:87
Roberts, Sheryl; Andreou, Chrysafis; Choi, Crystal et al. (2018) Sonophore-enhanced nanoemulsions for optoacoustic imaging of cancer. Chem Sci 9:5646-5657
Kossatz, Susanne; Carney, Brandon; Farley, Christopher et al. (2018) Direct Imaging of Drug Distribution and Target Engagement of the PARP Inhibitor Rucaparib. J Nucl Med 59:1316-1320
Donabedian, Patrick L; Kossatz, Susanne; Engelbach, John A et al. (2018) Discriminating radiation injury from recurrent tumor with [18F]PARPi and amino acid PET in mouse models. EJNMMI Res 8:59
Carney, Brandon; Kossatz, Susanne; Lok, Benjamin H et al. (2018) Target engagement imaging of PARP inhibitors in small-cell lung cancer. Nat Commun 9:176
Carlucci, Giuseppe; Carney, Brandon; Sadique, Ahmad et al. (2017) Evaluation of [18F]-ATRi as PET tracer for in vivo imaging of ATR in mouse models of brain cancer. Nucl Med Biol 48:9-15
Büchel, Gabriel E; Kossatz, Susanne; Sadique, Ahmad et al. (2017) cis-Tetrachlorido-bis(indazole)osmium(iv) and its osmium(iii) analogues: paving the way towards the cis-isomer of the ruthenium anticancer drugs KP1019 and/or NKP1339. Dalton Trans 46:11925-11941
Carney, Brandon; Kossatz, Susanne; Reiner, Thomas (2017) Molecular Imaging of PARP. J Nucl Med 58:1025-1030

Showing the most recent 10 out of 14 publications