Assessment of urinary 6-hydroxy-2,4-cyclohexadienyl mercapturic acid as a novel biomarker of benzene exposure.

Assessing benzene exposure is a public health priority due to its deleterious health effects and ubiquitous industrial and environmental sources of exposure. Phenyl mercapturic acid (PhMA) is a commonly used urinary biomarker to assess benzene exposure. However, recent work has identified significant interlaboratory variation in urinary PhMA concentrations related to methodological differences. In this study, we present urinary 6-hydroxy-2,4-cyclohexadienyl mercapturic acid (pre-PhMA), a metabolite that undergoes acid-catalyzed dehydration to form PhMA, as a novel and specific urinary biomarker for assessing benzene exposure. We developed and validated the first quantitative liquid chromatography-tandem mass spectrometry assay for measuring urinary concentrations of pre-PhMA. The pH effect on the method of ruggedness testing determined that pre-PhMA is stable across the normal human urine pH range and that neutral conditions must be maintained throughout quantification for robust and accurate measurement of urinary pre-PhMA concentrations. The method exhibited below 2 ng/mL sensitivity for pre-PhMA, linearity over three orders of magnitude, and precision and accuracy within 10%. Urinary pre-PhMA concentrations were assessed in 369 human urine samples. Smoking individuals exhibited elevated levels of pre-PhMA compared to non-smoking individuals. Furthermore, the relationship between benzene exposure and urinary pre-PhMA levels was explored by examining the correlation of pre-PhMA with 2-cyanoethyl mercapturic acid, a smoke exposure biomarker. The urinary biomarkers exhibited a positive correlation (r = 0.720), indicating that pre-PhMA levels increased with benzene exposure. The results of this study demonstrate that urinary pre-PhMA is a rugged and effective novel biomarker of benzene exposure that can be widely implemented for future biomonitoring studies.

GNAT toxins evolve toward narrow tRNA target specificities.

Type II toxin-antitoxin (TA) systems are two-gene modules widely distributed among prokaryotes. GNAT toxins associated with the DUF1778 antitoxins represent a large family of type II TAs. GNAT toxins inhibit cell growth by disrupting translation via acetylation of aminoacyl-tRNAs. In this work, we explored the evolutionary trajectory of GNAT toxins. Using LC/MS detection of acetylated aminoacyl-tRNAs combined with ribosome profiling, we systematically investigated the in vivo substrate specificity of an array of diverse GNAT toxins. Our functional data show that the majority of GNAT toxins are specific to Gly-tRNA isoacceptors. However, the phylogenetic analysis shows that the ancestor of GNAT toxins was likely a relaxed specificity enzyme capable of acetylating multiple elongator tRNAs. Together, our data provide a remarkable snapshot of the evolution of substrate specificity.

Targeting a Pathogenic Cysteine Mutation: Discovery of a Specific Inhibitor of Y279C SHP2.

An intriguing challenge of drug discovery is targeting pathogenic mutant proteins that differ from their wild-type counterparts by only a single amino acid. In particular, pathogenic cysteine mutations afford promising opportunities for mutant-specific drug discovery, due to the unique reactivity of cysteine's sulfhydryl-containing side chain. Here we describe the first directed discovery effort targeting a pathogenic cysteine mutant of a protein tyrosine phosphatase (PTP), namely Y279C Src-homology-2-containing PTP 2 (SHP2), which has been causatively linked to the developmental disorder Noonan syndrome with multiple lentigines (NSML). Through a screen of commercially available compounds that contain cysteine-reactive functional groups, we have discovered a small-molecule inhibitor of Y279C SHP2 (compound 99; IC50 ≈ 6 µM) that has no appreciable effect on the phosphatase activity of wild-type SHP2 or that of other homologous PTPs (IC50 ≫ 100 µM). Compound 99 exerts its specific inhibitory effect through irreversible engagement of Y279C SHP2's pathogenic cysteine residue in a manner that is time-dependent, is substrate-independent, and persists in the context of a complex proteome. To the best of our knowledge, 99 is the first specific ligand of a disease-causing PTP mutant to be identified. This study therefore provides both a starting point for the development of NSML-directed therapeutic agents and a precedent for the identification of mutant-specific inhibitors of other pathogenic PTP mutants.