To develop a mass spectrometric assay for the detection of sulfur mustard adducts with human serum albumin, the following steps were performed: quantitation of the binding of the agent to the protein by using [(14)C]sulfur mustard and analysis of acidic and tryptic digests of albumin from blood after exposure to sulfur mustard for identification of alkylation sites in the protein. The T5 fragment containing an alkylated cysteine could be detected in the tryptic digest with micro-LC/tandem MS analysis. Attempts to decrease the detection limit for in vitro exposure of human blood by analysis of the alkylated T5 fragment were not successful. After Pronase treatment of albumin, S-[2-[(hydroxyethyl)thio]ethyl]Cys-Pro-Phe was analyzed by means of micro-LC/tandem MS, allowing a detection limit for in vitro exposure of human blood of 10 nM, which is 1 order of magnitude lower than that obtained by means of modified Edman degradation. The analytical procedure could be successfully applied to the analysis of albumin samples from Iranian victims of the Iran-Iraq war.
The stereoselectivity of the phosphonylation reaction and the effects of adduct configuration on the aging process were examined for human acetylcholinesterase (HuAChE) and its selected active center mutants, using the four stereomers of 1,2,2-trimethylpropyl methylphosphonofluoridate (soman). The reactivity of wild type HuAChE toward the PS-soman diastereomers was 4.0-7.5 x 10(4)-fold higher than that toward the PR-diastereomers. Aging of the PSCS-somanyl-HuAChE conjugate was also >1.6 x 10(4)-fold faster than that of the corresponding PRCS-somanyl adduct, as shown by both reactivation and electrospray mass spectrometry (ESI/MS) experiments. On the other hand, both processes exhibited very limited sensitivity to the chirality of the alkoxy group Calpha of either PS- or PR-diastereomers. These stereoselectivities presumably reflect the relative participation of the enzyme in stabilization of the Michaelis complexes and in dealkylation of the respective covalent conjugates, and therefore could be utilized for further probing of the HuAChE active center functional architecture. Reactivities of HuAChE enzymes carrying replacements at the acyl pocket (F295A, F297A, and F295L/F297V) indicate that stereoselectivity with respect to the soman phosphorus chirality depends on the structure of this binding subsite, but this stereoselectivity cannot be explained only by limitation in the capacity to accommodate the PR-diastereomers. In addition, these acyl pocket enzyme mutants display some (5-10-fold) preference for the PRCR-soman over the PRCS-stereomer, while reactivity of the hydrophobic pocket mutant enzyme W86F toward the PRCS-soman resembles that of the wild type HuAChE. Residue substitutions in the H-bond network (E202Q, E450A, Y133F, and Y133A) and the hydrophobic pocket (F338A, W86A, W86F, and Y337A) result in a limited stereoselectivity for the PSCS- over the PSCR-stereomer. Aging of the PS-somanyl conjugates with all the HuAChE mutant enzymes tested practically lacked stereoselectivity with respect to the Calpha of the alkoxy moiety. Thus, the inherent asymmetry of the active center does not seem to affect the rate-determining step of the dealkylation process, possibly because both the PSCS- and the PSCR-somanyl moieties yield the same carbocationic intermediate.
As part of a program to develop methods for verification of alleged exposure to sulfur mustard, we synthesized and characterized the adducts most likely formed by alkylation of DNA with sulfur mustard: N7-[2-[(2-hydroxyethyl)thio]ethyl]guanine (1), bis[2-(guanin-7-yl)ethyl] sulfide (2), N3-[2-[(2-hydroxyethyl)thio]ethyl]adenine (3), and O6-[2-[(2-hydroxyethyl)thio]ethyl]-guanine and its 2'-deoxyguanosine derivative. Incubation of double-stranded calf thymus DNA and human blood with [35S]sulfur mustard in vitro followed by enzymatic degradation of the DNA and mild depurination afforded three major radioactive peaks upon HPLC analysis. These peaks were identified as 1-3 by coelution with the synthetic markers and mass spectrometric and electronic spectra. Compound 1 appeared to be the most abundant adduct, which is in agreement with previous investigations on DNA alkylation with sulfur mustard.
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