Excess electron transfer through one set of DNA duplexes comprising either one or two metal-mediated thymine-Hg -thymine base pairs was studied. Towards this end, the metal-mediated base pair(s) were introduced between an artificial nucleoside bearing a N,N,N',N'-tetramethyl-1,5-diaminonaphthalene derivative (dN, acting as a photoinducible electron donor) and 5-bromo-2'-deoxyuridine (dB, acting as an electron acceptor). Upon one-electron reduction, dB loses a bromide ion. The amount of unreacted dB remaining after irradiation-determined by LC/ICP-MS-was used to evaluate the charge-transfer efficiency across the metal-mediated base pair(s). Reference measurements with canonical adenine:thymine base pairs prove the applicability of this approach for the detection of charge transfer in DNA. The data indicate that, for the set of DNA duplexes under investigation, excess electron transfer across a thymine-Hg -thymine base pair proceeds with low efficiency, comparable to the transfer across a thymine:thymine mispair. Two contiguous thymine-Hg -thymine base pairs effectively shut down excess electron transfer.
The environmental micropollutant sulfamethoxazole (SMX) is susceptible to phototransformation by sunlight and UV-C light which is used for water disinfection. Depending on the environmental pH conditions SMX may be present as neutral or anionic species. This study systematically investigates the phototransformation of these two relevant SMX species using four different irradiation scenarios, i.e., a low, medium, and high pressure Hg lamp and simulated sunlight. The observed phototransformation kinetics are complemented by data from compound-specific stable isotope and transformation product analysis using isotope-ratio and high-resolution mass spectrometry (HRMS). Observed phototransformation kinetics were faster for the neutral than for the anionic SMX species (from 3.4 (LP lamp) up to 6.6 (HP lamp) times). Furthermore, four phototransformation products (with m/z 189, 202, 242, and 260) were detected by HRMS that have not yet been described for direct photolysis of SMX. Isotopic fractionation occurred only if UV-B and UV-A wavelengths prevailed in the emitted irradiation and was most pronounced for the neutral species with simulated sunlight (ε = -4.8 ± 0.1 ‰). Phototransformation of SMX with UV-C light did not cause significant isotopic fractionation. Consequently, it was possible to differentiate sunlight and UV-C light induced phototransformation of SMX. Thus, CSIA might be implemented to trace back wastewater point sources or to assess natural attenuation of SMX by sunlight photolysis. In contrast to the wavelength range, pH-dependent speciation of SMX hardly impacted isotopic fractionation.
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