Charles R. Iden

NH2-terminal Proline Acts as a Nucleophile in the Glycosylase/AP-Lyase Reaction Catalyzed by Escherichia coli Formamidopyrimidine-DNA Glycosylase (Fpg) Protein

Formamidopyrimidine-DNA glycosylase (Fpg) protein plays a prominent role in the repair of oxidatively damaged DNA in Escherichia coli. The protein possesses three enzymatic activities, hydrolysis of the N-glycosidic bond (DNA glycosylase), β-elimination (AP lyase), and δ-elimination; these functions act in a concerted manner to excise oxidized deoxynucleosides from duplex DNA. Schiff base formation between the enzyme and substrate has been demonstrated (Tchou, J., and Grollman, A. P. (1995) J. Biol. Chem. 270, 11671-11677); this protein-DNA complex can be trapped by reduction with sodium borohydride. By digesting the stable, covalently linked intermediate with proteases and determining the accurate mass of the products by negative electrospray ionization-mass spectrometry, we show that the N-terminal proline of Fpg protein is linked to DNA and, therefore, is identified as the nucleophile that initiates the catalytic excision of oxidized bases from DNA. This experimental approach may be applicable to the analysis of other protein-DNA complexes.

Analysis of nonylphenol and nonylphenol ethoxylates in environmental samples by mixed-mode high-performance liquid chromatography-electrospray mass spectrometry

A new method is described based on mixed-mode high-performance liquid chromatography with electrospray mass spectrometry detection for comprehensive quantitative analysis of nonylphenol (NP) and nonylphenol ethoxylates (NPEOs) in wastewater and sediment. Efficient separation, reduced band broadening, and high sensitivity were achieved by employing a methanol-water gradient on a mixed-solvent gel filtration column designed for MS interfacing. Quantitative accuracy and precision of the method were improved by the use of custom-synthesized [13C6]NPEO analogs as isotope-dilution surrogate standards. Method detection limits for NP and individual NPEOs ranged from I to 55 pg injected on column.

Biomonitoring of Aristolactam-DNA Adducts in Human Tissues Using Ultra-Performance Liquid Chromatography/Ion-Trap Mass Spectrometry

Aristolochic acids (AAs) are a structurally related family of nephrotoxic and carcinogenic nitrophenanthrene compounds found in Aristolochia herbaceous plants, many of which have been used worldwide for medicinal purposes. AAs have been implicated in the etiology of so-called Chinese herbs nephropathy and of Balkan endemic nephropathy. Both of these disease syndromes are associated with carcinomas of the upper urinary tract (UUC). 8-Methoxy-6-nitrophenanthro-[3,4-d]-1,3-dioxolo-5-carboxylic acid (AA-I) is a principal component of Aristolochia herbs. Following metabolic activation, AA-I reacts with DNA to form aristolactam (AL-I)-DNA adducts. We have developed a sensitive analytical method, using ultraperformance liquid chromatography-electrospray ionization/multistage mass spectrometry (UPLC-ESI/MS(n)) with a linear quadrupole ion-trap mass spectrometer, to measure 7-(deoxyadenosin-N(6)-yl) aristolactam I (dA-AL-I) and 7-(deoxyguanosin-N(2)-yl) aristolactam I (dG-AL-I) adducts. Using 10 μg of DNA for measurements, the lower limits of quantitation of dA-AL-I and dG-AL-I are, respectively, 0.3 and 1.0 adducts per 10(8) DNA bases. We have used UPLC-ESI/MS(n) to quantify AL-DNA adducts in tissues of rodents exposed to AA and in the renal cortex of patients with UUC who reside in Taiwan, where the incidence of this uncommon cancer is the highest reported for any country in the world. In human tissues, dA-AL-I was detected at levels ranging from 9 to 338 adducts per 10(8) DNA bases, whereas dG-AL-I was not found. We conclude that UPLC-ESI/MS(n) is a highly sensitive, specific and robust analytical method, positioned to supplant (32)P-postlabeling techniques currently used for biomonitoring of DNA adducts in human tissues. Importantly, UPLC-ESI/MS(n) could be used to document exposure to AA, the toxicant responsible for AA nephropathy and its associated UUC.

Characterization of a Cross-Linked DNA- Endonuclease VIII Repair Complex by Electrospray Ionization Mass Spectrometry

Electrospray mass spectrometry techniques were used to characterize components of the active site in Endonuclease VIII by identifying the amino acid sequence and the binding site for a tryptic peptide derived from Endo VIII in a cross-linked DNA-peptide complex. Endo VIII, a DNA repair enzyme with both glycosylase and lyase activities, was covalently bound to a thymidine glycol-containing oligodeoxynucleotide duplex by converting a transient Schiff base formed during the course of the glycosylase activity to a stable covalent bond by chemical reduction with sodium borohydride. After tryptic digestion of the initial product, the identification of the cross-linked peptide was deduced initially from the molecular mass of the tryptic product obtained by negative ion electrospray mass analysis. Nanospray tandem mass spectrometry (MS/MS) analysis of the tryptic product corroborated the molecular mass of the peptide fragment and verified the point of attachment to the oligomer, but failed to produce sufficient fragmentation to sequence the peptide completely. Direct evidence for the amino acid sequence of the peptide was obtained after enzymatic digestion of the DNA portion of the cross-linked DNA-peptide product and analysis by negative ion nanospray MS/MS. Examination of the ions from collision induced fragmentation disclosed that this substance was the N-terminal tryptic fragment of Endo VIII cross-linked to a portion of the oligomer, and that the N-terminal proline from Endo VIII was covalently bound to the residual deoxyribose moiety at the original location of the thymine glycol in the oligomer.

DNA adducts of aristolochic acid II: total synthesis and site-specific mutagenesis studies in mammalian cells

Aristolochic acids I and II (AA-I, AA-II) are found in all Aristolochia species. Ingestion of these acids either in the form of herbal remedies or as contaminated wheat flour causes a dose-dependent chronic kidney failure characterized by renal tubulointerstitial fibrosis. In ∼50% of these cases, the condition is accompanied by an upper urinary tract malignancy. The disease is now termed aristolochic acid nephropathy (AAN). AA-I is largely responsible for the nephrotoxicity while both AA-I and AA-II are genotoxic. DNA adducts derived from AA-I and AA-II have been isolated from renal tissues of patients suffering from AAN. We describe the total synthesis, de novo, of the dA and dG adducts derived from AA-II, their incorporation site-specifically into DNA oligomers and the splicing of these modified oligomers into a plasmid construct followed by transfection into mouse embryonic fibroblasts. Analysis of the plasmid progeny revealed that both adducts blocked replication but were still partly processed by DNA polymerase(s). Although the majority of coding events involved insertion of correct nucleotides, substantial misincorporation of bases also was noted. The dA adduct is significantly more mutagenic than the dG adduct; both adducts give rise, almost exclusively, to misincorporation of dA, which leads to AL-II-dA→T and AL-II-dG→T transversions.

Analysis of modified deoxynucleosides by electrospray ionization mass spectrometry

Abstract Electrospray mass spectra for selected modified deoxynucleosides and deoxynucleoside monophosphates have been determined. Protonated molecular ions are abundant in the positive ion spectrum, while (M-H) appears in the negative ion spectrum. However, fragment ion intensities are usually low in both spectra. Conditions which promote collision-induced dissociation within the electrospray source facilitate fragment ion formation, and the intensity of BH2 + and S+ (positive ion spectrum) and (M-BH) and B (negative ion spectrum) are enhanced by increasing the skimmer cone voltage. MH+ was detected with as little as 3 pmol of deoxynucleoside, and the protonated molecular ion intensity is linear with respect to analyte concentration over two orders of magnitude.

An Improved Method for The Preparation Of The Phosphoramidites Of Modified 2′-Deoxynucleotides: Incorporation Of 8-Oxo-2′-Deoxy-7H-Guanosine Into Synthetic Oligomers

Abstract 3′ -O-(Diisopropylamino-2-cyanoethoxyphosphinyl)-5′ -0-(4, 4′ -dimethoxytrityl)-N2-isobutyryl-8-oxo-2′-deoxy-7H-guanosine was synthesized and used for the introduction of an 8−0×0−2′-deoxy-7H-guanosine residue into a DNA oligomer by means of automated synthesis. A modification of the preparation of the phosphoramidite markedly improves the coupling efficiency in the oligomer synthesis in this and several other cases that were tested.

Proteomic Approach to Identification of Proteins Reactive for Abasic Sites in DNA

Apurinic/apyrimidinic (AP) sites, a prominent type of DNA damage, are repaired through the base excision repair mechanism in both prokaryotes and eukaryotes and may interfere with many other cellular processes. A full repertoire of AP site-binding proteins in cells is presently unknown, preventing reliable assessment of harm inflicted by these ubiquitous lesions and of their involvement in the flux of DNA metabolism. We present a proteomics-based strategy for assembling at least a partial catalogue of proteins capable of binding AP sites in DNA. The general scheme relies on the sensitivity of many AP site-bound protein species to NaBH4 cross-linking. An affinity-tagged substrate is used to facilitate isolation of the cross-linked species, which are then separated and analyzed by mass spectrometry methods. We report identification of seven proteins from Escherichia coli (AroF, DnaK, MutM, PolA, TnaA, TufA, and UvrA) and two proteins from bakers’ yeast (ARC1 and Ygl245wp) reactive for AP sites in this system.

Aristolochic acid I metabolism in the isolated perfused rat kidney.

Aristolochic acids are natural nitro-compounds found globally in the plant genus Aristolochia that have been implicated in the severe illness in humans termed aristolochic acid nephropathy (AAN). Aristolochic acids undergo nitroreduction, among other metabolic reactions, and active intermediates arise that are carcinogenic. Previous experiments with rats showed that aristolochic acid I (AA-I), after oral administration or injection, is subjected to detoxication reactions to give aristolochic acid Ia, aristolactam Ia, aristolactam I, and their glucuronide and sulfate conjugates that can be found in urine and feces. Results obtained with whole rats do not clearly define the role of liver and kidney in such metabolic transformation. In this study, in order to determine the specific role of the kidney on the renal disposition of AA-I and to study the biotransformations suffered by AA-I in this organ, isolated kidneys of rats were perfused with AA-I. AA-I and metabolite concentrations were determined in perfusates and urine using HPLC procedures. The isolated perfused rat kidney model showed that AA-I distributes rapidly and extensively in kidney tissues by uptake from the peritubular capillaries and the tubules. It was also established that the kidney is able to metabolize AA-I into aristolochic acid Ia, aristolochic acid Ia O-sulfate, aristolactam Ia, aristolactam I, and aristolactam Ia O-glucuronide. Rapid demethylation and sulfation of AA-I in the kidney generate aristolochic acid Ia and its sulfate conjugate that are voided to the urine. Reduction reactions to give the aristolactam metabolites occur to a slower rate. Renal clearances showed that filtered AA-I is reabsorbed at the tubules, whereas the metabolites are secreted. The unconjugated metabolites produced in the renal tissues are transported to both urine and perfusate, whereas the conjugated metabolites are almost exclusively secreted to the urine.

Impact of α-Hydroxy-Propanodeoxyguanine Adducts on DNA Duplex Energetics: Opposite Base Modulation and Implications for Mutagenicity and Genotoxicity

Acrolein is an alpha,beta-unsaturated aldehyde that is a major environmental pollutant, as well as a product of cellular metabolism. DNA bases react with acrolein to form two regioisomeric exocyclic guanine adducts, namely gamma-hydroxy-propanodeoxyguanosine (gamma-OH-PdG) and its positional isomer alpha-hydroxy-propanodeoxyguanosine (alpha-OH-PdG). The gamma-OH-PdG isomer adopts a ring-opened conformation with minimal structural perturbation of the DNA host duplex. Conversely, the alpha-OH-PdG isomer assumes a ring-closed conformation that significantly disrupts Watson-Crick base-pair alignments within the immediate vicinity of the damaged site. We have employed a combination of calorimetric and spectroscopic techniques to characterize the thermodynamic origins of these lesion-induced structural alterations. Specifically, we have assessed the energetic impact of alpha-OH-PdG centered within an 11-mer duplex by hybridizing the adduct-containing oligonucleotide with its complementary strand harboring a central base N [where N = C or A], yielding a pair of duplexes containing the nascent lesion (alpha-OH-PdG.C) or mismatched adduct (alpha-OH-PdG.A), respectively. Our data reveal that the nascent lesion is highly destabilizing, whereas its mismatched counterpart partially ameliorates alpha-OH-PdG-induced destabilization. Collectively, our data provide energetic characterizations of the driving forces that modulate error-free versus error-prone DNA translesion synthesis. The biological implications of our findings are discussed in terms of energetically probing acrolein-mediated mutagenicity versus adduct-induced genotoxicity.