A photoadduct is formed between the adenine (A) and thymine (T) bases of the deoxydinucleoside monophosphate d(TpA) when it is irradiated at 254 nanometers in aqueous solution. Treatment of the photoadduct with acid converts it specifically into a fluorescent hydrolysis product, C7H7N3O, incorporating the position-8 carbon of adenine and the methyl group of thymine. Isolation of the fluorescent hydrolysis product from acid hydrolyzates of oligo- and polydeoxyribonucleotides has shown that the photoadduct is formed by ultraviolet irradiation of d(pTpA), d(TpApT), d(TpApTpA), poly(dA-dT), and both single- and double-stranded DNA.
When d(T-A) is irradiated at 254 nm in aqueous solution an internal photoadduct is formed between its constituent adenine and thymine bases. The resultant photoproduct, designated TA*, arises from a singlet excited state precursor; a similar photoreaction is not observed with d(C-A) or d(T-G). In contradistinction, irradiation of d(T-A) in frozen aqueous solution yields a dimeric photoproduct in which two d(T-A) molecules are coupled together by a (6-4) photoadduct linkage between their respective thymine bases. Both photoproducts have been extensively characterised by a combination of electron impact and fast atom bombardment mass spectrometry, UV, CD, 1H NMR and fluorescence spectroscopy. Acid treatment of TA* gives 6-methylimidazo[4,5-b]pyridin-5-one whose identity was established by an independent chemical synthesis involving photorearrangement of 6-methyl-imidazo[4,5-b]pyridine N(4)-oxide. A tentative mechanism is presented to account for the acid degradation of TA*. The structure of the dimeric ice photoproduct follows from its cleavage, by snake venom phosphodiesterase, to 5'-dAMP and the (6-4) bimolecular photoadduct of thymidine; on acid hydrolysis it gives adenine and 6-(5'-methyl-2'-oxopyrimidin-4'-yl) thymine.
Isotopic exchange of mass-selected odd-and even-electron molecular ions of aromatic compounds upon collision with deuterated gases was investigated as a function of reagent gas, interaction time and collision energy. Use of ND, as reagent allows exchange of all active hydrogens for the compound types studied, providing a count of the total number of active hydrogens present in the analyte. CH,OD exchanges specific types of active hydrogens, such as phenolic and carboxylic hydrogens, without exchanging amino hydrogens. This selectivity assists in the identification and enumeration of different types of active hydrogens present in polyfunctional compounds. The H-D exchange patterns serve to differentiate isomeric aromatic compounds containing methoxy, amino, hydroxy and carboxylic acid substituents. Trapping of mass-selected ions in the collision region of a triple quadrupole mass spectrometer greatly enhances the degree of H-D exchange, thereby facilitating determination of the number of active hydrogens in the analyte. Triple stage mass spectrometric experiments, performed in a pentaquadrupole mass spectrometer, help elucidate the exchange process. Isotopic exchange in the collision region of a tandem mass spectrometer also provides insights into the site of protonation in molecules containing several functional groups. The proximity of the functional groups and the proton affinity difference between the analyte and the reagent gas me important factors in site-specific H-D exchange in polyfunctional compounds. An investigation of the effects of collision energy reveals that cluster ion formation plays a major role in the exchange mechanism operating in the triple quadrupole and that H-D exchange, ion-molecule adduct formation and endothermic fragmentation are competitive reaction channels. labelled reagent gas with the sample ion.' 7 , 3 1 , 3 2 Th US,
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