Tumor Cell-Specific 2'-Fluoro RNA Aptamer Conjugated with -Dodecaborate As A Potential Agent for Boron Neutron Capture Therapy

Overview

Journal Int J Mol Sci

Publisher MDPI

Specialties Biochemistry
Chemistry
Molecular Biology

Date 2021 Jul 24

PMID 34298946

Citations 8

Authors

Mariya A Vorobyeva

Maya A Dymova

Darya S Novopashina

Elena V Kuligina

Valentina V Timoshenko

Iaroslav A Kolesnikov

Sergey Yu Taskaev

Vladimir A Richter

Alya G Venyaminova

Affiliations

Soon will be listed here.

Abstract

Boron neutron capture therapy (BNCT) is a binary radiotherapeutic approach to the treatment of malignant tumors, especially glioblastoma, the most frequent and incurable brain tumor. For successful BNCT, a boron-containing therapeutic agent should provide selective and effective accumulation of B isotope inside target cells, which are then destroyed after neutron irradiation. Nucleic acid aptamers look like very prospective candidates for carrying B to the tumor cells. This study represents the first example of using 2'-F-RNA aptamer GL44 specific to the human glioblastoma U-87 MG cells as a boron delivery agent for BNCT. The -dodecaborate residue was attached to the 5'-end of the aptamer, which was also labeled by the fluorophore at the 3'-end. The resulting bifunctional conjugate showed effective and specific internalization into U-87 MG cells and low toxicity. After incubation with the conjugate, the cells were irradiated by epithermal neutrons on the Budker Institute of Nuclear Physics neutron source. Evaluation of the cell proliferation by real-time cell monitoring and the clonogenic test revealed that boron-loaded aptamer decreased specifically the viability of U-87 MG cells to the extent comparable to that of B-boronophenylalanine taken as a control. Therefore, we have demonstrated a proof of principle of employing aptamers for targeted delivery of boron-10 isotope in BNCT. Considering their specificity, ease of synthesis, and large toolkit of chemical approaches for high boron-loading, aptamers provide a promising basis for engineering novel BNCT agents.

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