DNA Adductomics by mass tag prelabeling.

RATIONALE: As a new approach to DNA adductomics, we directly reacted intact, double-stranded (ds)-DNA under warm conditions with an alkylating mass tag followed by analysis by liquid chromatography/mass spectrometry. This method is based on the tendency of adducted nucleobases to locally disrupt the DNA structure (forming a "DNA bubble") potentially increasing exposure of their nucleophilic (including active hydrogen) sites for preferential alkylation. Also encouraging this strategy is that the scope of nucleotide excision repair is very broad, and this system primarily recognizes DNA bubbles. METHODS: A cationic xylyl (CAX) mass tag with limited nonpolarity was selected to increase the retention of polar adducts in reversed-phase high-performance liquid chromatography (HPLC) for more detectability while maintaining resolution. We thereby detected a diversity of DNA adducts (mostly polar) by the following sequence of steps: (1) react DNA at 45°C for 2 h under aqueous conditions with CAX-B (has a benzyl bromide functional group to label active hydrogen sites) in the presence of triethylamine; (2) remove residual reagents by precipitating and washing the DNA (a convenient step); (3) digest the DNA enzymatically to nucleotides and remove unlabeled nucleotides by nonpolar solid-phase extraction (also a convenient step); and (4) detect CAX-labeled, adducted nucleotides by LC/MS2 or a matrix-assisted laser desorption/ionization (MALDI)-MS technique. RESULTS: Examples of the 42 DNA or RNA adducts detected, or tentatively so based on accurate mass and fragmentation data, are as follows: 8-oxo-dGMP, ethyl-dGMP, hydroxyethyl-dGMP (four isomers, all HPLC-resolved), uracil-glycol, apurinic/apyrimidinic sites, benzo[a]pyrene-dGMP, and, for the first time, benzoquinone-hydroxymethyl-dCMP. Importantly, these adducts are detected in a single procedure under a single set of conditions. Sensitivity, however, is only defined in a preliminary way, namely the latter adduct seems to be detected at a level of about 4 adducts in 109 nucleotides (S/N ~30). CONCLUSIONS: CAX-Prelabeling is an emerging new technique for DNA adductomics, providing polar DNA adductomics in a practical way for the first time. Further study of the method is encouraged to better characterize and extend its performance, especially in scope and sensitivity.

Jettison-MS of Nucleic Acid Species.

While MALDI-MS of intact genomic DNA is unheard of, actually many DNA adducts can be detected in this way under certain MALDI conditions: relatively high molar ratio of DNA nucleobases to matrix (0.01 to 0.3), hot matrix (CCA), and high laser fluence. This is because many DNA adducts create "bubbles" on dsDNA (disruption of base pairing), making it easier for these adducts as modified nucleobases to be jettisoned by the laser-derived energy of MALDI (jettison mass spectrometry or JeMS). The method also works for other nucleic acid species, namely nucleobases, nucleosides, nucleotides, and RNA. Examples of what we have detected in this way are as follows: methyladenine in E. coli DNA, 5-hydroxymethylcytosine in human brain DNA, melphalan-adenine in leukocyte DNA from patients on corresponding chemotherapy, wybutosine in tRNA, benzyl DNA adducts in E. coli cell culture treated with benzyl bromide, and various DNA adducts formed in test tube exposure experiments with calf thymus DNA. Noteworthy, in the chemotherapy study, principle component analysis of the data encourages the hypothesis that patient DNA undergoes much more damage than just melphalan adducts. Overall, our work leads to the preliminary generalization that about 5 fmol of a nucleobase deficient in base pairing, and present in a MALDI spot, will be detected by JeMS (on the equipment that we used), irrespective of the type of nucleic acid species which houses it, as long as the nucleobase is relatively basic such as A, C, or G.

The response of Escherichia coli to the alkylating agents chloroacetaldehyde and styrene oxide.

DNA damage is ubiquitous and can arise from endogenous or exogenous sources. DNA-damaging alkylating agents are present in environmental toxicants as well as in cancer chemotherapy drugs and are a constant threat, which can lead to mutations or cell death. All organisms have multiple DNA repair and DNA damage tolerance pathways to resist the potentially negative effects of exposure to alkylating agents. In bacteria, many of the genes in these pathways are regulated as part of the SOS reponse or the adaptive response. In this work, we probed the cellular responses to the alkylating agents chloroacetaldehyde (CAA), which is a metabolite of 1,2-dichloroethane used to produce polyvinyl chloride, and styrene oxide (SO), a major metabolite of styrene used in the production of polystyrene and other polymers. Vinyl chloride and styrene are produced on an industrial scale of billions of kilograms annually and thus have a high potential for environmental exposure. To identify stress response genes in E. coli that are responsible for tolerance to the reactive metabolites CAA and SO, we used libraries of transcriptional reporters and gene deletion strains. In response to both alkylating agents, genes associated with several different stress pathways were upregulated, including protein, membrane, and oxidative stress, as well as DNA damage. E. coli strains lacking genes involved in base excision repair and nucleotide excision repair were sensitive to SO, whereas strains lacking recA and the SOS gene ybfE were sensitive to both alkylating agents tested. This work indicates the varied systems involved in cellular responses to alkylating agents, and highlights the specific DNA repair genes involved in the responses.