Potassium peroxymonosulfate (oxone)--an efficient oxidizing agent for phosphothio compounds

Oxidation of Organic Compounds in Water by Unactivated Peroxymonosulfate

Peroxymonosulfate (HSO₅^- and PMS) is an optional bulk oxidant in advanced oxidation processes (AOPs) for treating wastewaters. Normally, PMS is activated by the input of energy or reducing agent to generate sulfate or hydroxyl radicals or both. This study shows that PMS without explicit activation undergoes direct reaction with a variety of compounds, including antibiotics, pharmaceuticals, phenolics, and commonly used singlet-oxygen (¹O₂) traps and quenchers, specifically furfuryl alcohol (FFA), azide, and histidine. Reaction time frames varied from minutes to a few hours at pH 9. With the use of a test compound with intermediate reactivity (FFA), electron paramagnetic resonance (EPR) and scavenging experiments ruled out sulfate and hydroxyl radicals. Although ¹O₂ was detected by EPR and is produced stoichiometrically through PMS self-decomposition, ¹O₂ plays only a minor role due to its efficient quenching by water, as confirmed by experiments manipulating the ¹O₂ formation rate (addition of H₂O₂) or lifetime (deuterium solvent isotope effect). Direct reactions with PMS are highly pH- and ionic-strength-sensitive and can be accelerated by (bi)carbonate, borate, and pyrophosphate (although not phosphate) via non-radical pathways. The findings indicate that direct reaction with PMS may steer degradation pathways and must be considered in AOPs and other applications. They also signal caution to researchers when choosing buffers as well as ¹O₂ traps and quenchers.

Synthesis of nucleoside alpha-thiotriphosphates via an oxathiaphospholane approach

[reaction: see text]. Nucleoside 5'-O-(alpha-thiotriphosphates) were obtained in reactions of the appropriate nucleoside 5'-O-(2-thio-1,3,2-oxathiaphospholanes) with pyrophosphate in the presence of DBU. The presented method allows also for preparation of alpha-seleno congeners and corresponding alpha-modified diphosphates.

Comparison of the cleavage profiles of oligonucleotide duplexes with or without phosphorothioate linkages by using a chemical nuclease probe

A manganese porphyrin complex, Mn-TMPyP, associated with KHSO(5) is a chemical nuclease able to selectively recognize the minor groove of three consecutive AT base pairs of DNA and to mediate very precise cleavage chemistry at that particular site. This specific recognition and cleavage were used to probe the accessibility of the minor groove of DNA duplexes composed of one phosphodiester strand and one phosphorothioate strand. The cleavage of 5'-GCAAAAGC/5'-GCTTTTGC duplexes by Mn-TMPyP/KHSO(5) was monitored by HPLC coupled to electrospray mass analysis. Each single strand was synthesized with all-phosphate, all- Rp-phosphorothioate and all- Sp-phosphorothioate internucleotide bonds. We found that the manganese porphyrin was able to recognize its favorite (AT)(3)-box binding site within the heteroduplexes, as in the case of natural DNA. Molecular modeling studies on the interactions of the reactive porphyrin manganese-oxo species with both types of duplexes confirmed the experimental data.

Direct lactonization of alkenols via osmium tetroxide-mediated oxidative cleavage

[reaction: see text] A highly efficient, mild, and simple protocol is presented for the tandem OsO(4)-mediated oxidative cleavage/oxidative lactonization of alkenols to lactones. The protocol couples the OsO(4)-catalyzed oxidative cleavage of olefins with Oxone as the co-oxidant with the direct oxidation of aldehydes in alcoholic solvents to their corresponding esters.