Abstract
DNA has the genetic information storage and transmission capacity according to the sequential order of the monomer and creates a central role in the chemical evolution by copying itself with the proliferation feature. Watson-Crick base pairs define two base pairs with hydrogen bonds. If metal coordination bonds replace hydrogen bonds more stable alternative metallo-DNA sequence can be established. If the replication feature can be obtained for the metallo-DNA, this will greatly benefit the creation of DNA computer keys. In this study, a new type of benzimidazole based metallo-DNA sensors consisting of a connector unit that unsaturated azinil bridge linked to Watson-Crick base pairs with Ni2+, Hg2+, Zn2+, Ag+, Pt2+, Pd2+ metal cations and a benzimidazole has been designed. Absorption and emission spectrum of the newly designed aqua medium based fluorophore and their metallo-DNA sensors with selected cations have been theoretically investigated by using DFT method. The logic gates of selected possible sensors which response in the visible region have also been examined in detail in acidic and water phase. As a result of calculated absorption-emission spectrum data show that T-Hg-A-Bnz, A-Ni-T-Bnz, C-Pt-G-Bnz, C-Ni-C-Bnz complexes produce OR gate. T-Zn-T-Bnz and G-Pt-C-Bnz results demonstrated XOR and AND logic gate, respectively.
Highlights
Today, development of biomolecular structures is generally based on supramolecules that include non-covalent interactions, such as hydrogen bonds, hydrophobic effects and metal coordination bonds [1] [2] [3] [4]
A new type of benzimidazole based metallo-DNA sensors consisting of a connector unit that unsaturated azinil bridge linked to Watson-Crick base pairs with Ni2+, Hg2+, Zn2+, Ag+, Pt2+, Pd2+ metal cations and a benzimidazole has been designed
As a result of calculated absorption-emission spectrum data show that T-Hg-A-Bnz, A-Ni-T-Bnz, C-Pt-G-Bnz, C-Ni-C-Bnz complexes produce OR gate
Summary
Development of biomolecular structures is generally based on supramolecules that include non-covalent interactions, such as hydrogen bonds, hydrophobic effects and metal coordination bonds [1] [2] [3] [4]. Metallo-DNA sensors that have new fluorescent characteristics and the capability to work in aqueous mediums have been designed by binding metals (Hg2+, Ag+, Ni2+, Pb2+, Pt2+, Zn2+) that can provide them coordination, especially planar coordination, to Watson-Crick base pairs and their reversible and changeable optical characteristics in acidic mediums have been investigated and possible logic gates have been suggested Since these designed sensors are expected to be potential keys for the DNA computer technology, we expect them to contribute greatly to science and technology applications
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