Radiation-Mediated Tumor Growth Inhibition Is Significantly Enhanced with Redox-Active Compounds That Cycle with Ascorbate

Authors

Artak Tovmasyan, Duke University School of Medicine
Jacqueline C. Bueno-Janice, Duke University School of Medicine
Melba C. Jaramillo, The University of Arizona
Romulo S. Sampaio, Duke University School of Medicine
Julio S. Reboucas, Universidade Federal da Paraíba
Natalia Kyui, Bank of Canada
Ludmil Benov, Kuwait University
Brian Deng, Palo Alto Veterans Institute for Research
Ting Ting Huang, Stanford University School of Medicine
Margaret E. Tome, The University of Arizona
Ivan Spasojevic, Duke University School of Medicine
Ines Batinic-Haberle, Duke University School of Medicine

Document Type

Article

Abstract

Aims: We aim here to demonstrate that radiation (RT) enhances tumor sensitization by only those Mn complexes that are redox active and cycle with ascorbate (Asc), thereby producing H2O2 and utilizing it subsequently in protein S-glutathionylation in a glutathione peroxidase (GPx)-like manner. In turn, such compounds affect cellular redox environment, described by glutathione disulfide (GSSG)/glutathione (GSH) ratio, and tumor growth. To achieve our goal, we tested several Mn complexes of different chemical and physical properties in cellular and animal flank models of 4T1 breast cancer cell. Four other cancer cell lines were used to substantiate key findings. Results: Joint administration of cationic Mn porphyrin (MnP)-based redox active compounds, MnTE-2-PyP5+ or MnTnBuOE-2-PyP5+ with RT and Asc contributes to high H2O2 production in cancer cells and tumor, which along with high MnP accumulation in cancer cells and tumor induces the largest suppression of cell viability and tumor growth, while increasing GSSG/GSH ratio and levels of total S-glutathionylated proteins. Redox-inert MnP, MnTBAP3- and two other different types of redox-active Mn complexes (EUK-8 and M40403) were neither efficacious in the cellular nor in the animal model. Such outcome is in accordance with their inability to catalyze Asc oxidation and mimic GPx. Innovation: We provided here the first evidence how structure-activity relationship between the catalytic potency and the redox properties of Mn complexes controls their ability to impact cellular redox environment and thus enhance the radiation and ascorbate-mediated tumor suppression. Conclusions: The interplay between the accumulation of cationic MnPs and their potency as catalysts for oxidation of Asc, protein cysteines, and GSH controls the magnitude of their anticancer therapeutic effects.

Keywords

ascorbate, EUK-8, M40403, MnTE-2-PyP 5+, MnTnBuOE-2-PyP 5+, radiosensitization, SOD mimics

Publication Date

11-1-2018

Publication Title

Antioxidants and Redox Signaling

ISSN

15230864

E-ISSN

15577716

Volume

29

Issue

13

First Page

1196

Last Page

1214

PubMed ID

29390861

Digital Object Identifier (DOI)

10.1089/ars.2017.7218

Recommended Citation

Tovmasyan, Artak; Bueno-Janice, Jacqueline C.; Jaramillo, Melba C.; Sampaio, Romulo S.; Reboucas, Julio S.; Kyui, Natalia; Benov, Ludmil; Deng, Brian; Huang, Ting Ting; Tome, Margaret E.; Spasojevic, Ivan; and Batinic-Haberle, Ines, "Radiation-Mediated Tumor Growth Inhibition Is Significantly Enhanced with Redox-Active Compounds That Cycle with Ascorbate" (2018). Translational Neuroscience. 1289.
https://scholar.barrowneuro.org/neurobiology/1289