Fluorescent
beacons based on silver (Ag) clusters for DNA/RNA detection
represent a new type of turn-on probe that fluoresces upon hybridization
to target nucleobase sequences. Physical–chemical mechanisms
of their fluorescence activation still remain poorly understood. We
studied in detail the fluorescence activation of dark Ag clusters
induced by interactions of Ag–DNA complexes with different
DNA sequences. In all cases, the final result depends neither on the
location of the precursors (dark clusters) nor on their spectral properties.
The reaction of fluorescence activation is a process similar to the
growth of fluorescent silver clusters on dsDNA matrices. In both cases,
reactants are dark clusters and two adjacent DNA strands. The latter
form a double-stranded template for cluster nucleation. We found the
optimized structure of a green fluorescent Ag4
+2 cluster assembled on a C3/C3 DNA dimer in two different ssDNA pairs
using QM modeling. The calculated absorption spectra match nicely
the experimental ones, which proves the optimized structures. We conclude
that apparent fluorescence activation in the studied systems results
from reassembling Ag clusters on the new dsDNA template formed upon
hybridization with the target. The suggested mechanism of “fluorescence
activation” offers a way to design new light-up DNA probes.
Two DNA strands making up the dsDNA template providing a high yield
of bright Ag clusters can be used as the halves with the “stick”
tails hybridizing with the base sequence of the target DNA. In this
way, we have designed a light-up Ag cluster probe for β-actin mRNA.
Pterins are an inseparable part of living organisms. Pterins participate in metabolic reactions mostly as tetrahydropterins. Dihydropterins are usually intermediates of these reactions, whereas oxidized pterins can be biomarkers of diseases. In this review, we analyze the available data on the quantum chemistry of unconjugated pterins as well as their photonics. This gives a comprehensive overview about the electronic structure of pterins and offers some benefits for biomedicine applications: (1) one can affect the enzymatic reactions of aromatic amino acid hydroxylases, NO synthases, and alkylglycerol monooxygenase through UV irradiation of H4pterins since UV provokes electron donor reactions of H4pterins; (2) the emission properties of H2pterins and oxidized pterins can be used in fluorescence diagnostics; (3) two-photon absorption (TPA) should be used in such pterin-related infrared therapy because single-photon absorption in the UV range is inefficient and scatters in vivo; (4) one can affect pathogen organisms through TPA excitation of H4pterin cofactors, such as the molybdenum cofactor, leading to its detachment from proteins and subsequent oxidation; (5) metal nanostructures can be used for the UV-vis, fluorescence, and Raman spectroscopy detection of pterin biomarkers. Therefore, we investigated both the biochemistry and physical chemistry of pterins and suggested some potential prospects for pterin-related biomedicine.
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