Retinoblastoma: Magnetic Isotope Effects Might Make a Difference in the Current Anti-Cancer Research Strategy

Bukhvostov, Alexander A.; Dvornikov, Anton S.; Ermakov, Kirill V.; Kurapov, Pavel B.; Kuznetsov, Dmitry A.

doi:10.14712/18059694.2017.101

Acta Medica > Archive > 2017, Vol. 60 > Issue 2 > Retinoblastoma: Magnetic Isotope Effects…

Acta Med. 2017, 60: 93-96

https://doi.org/10.14712/18059694.2017.101

Retinoblastoma: Magnetic Isotope Effects Might Make a Difference in the Current Anti-Cancer Research Strategy

Alexander A. Bukhvostov, Anton S. Dvornikov, Kirill V. Ermakov, Pavel B. Kurapov, Dmitry A. Kuznetsov

School of Biomedicine, Faculty of Medicine, N. I. Pirogoff Russian National Research Medical University, Moscow, Russia

Received March 30, 2016
Accepted June 27, 2017

Human retinoblastoma cells were proven to possess some very unusual DNApolβ species. Being 23.5 kDa monomers, which itself is not common for the DNApolβ superfamily members, these chromatin associated proteins manifests most of the DNApolβ-specifc functional peculiarities making them legitimate targets for DNA repair cytostatic inhibitors. Particularly, these tumor specific enzymes were found to be very sensitive to ²⁵Mg²⁺-, ⁴³Ca²⁺- and ⁶⁷Zn²⁺-promoted magnetic isotope effects (MIE) caused a marked DNA sequence growth limitation as well as a formation of the size-invalid, i.e. too short in length, DNA fragments, totally inappropriate for the DNA repair purpose. This MIE-DNApolβ match may serve a starting point for further move towards the paramagnetic path in current developments of anti-cancer strategies.