Metabolic studies of explosives. 1--EI and CI mass spectrometry of metabolites of 2,4,6-trinitrotoluene

A series of metabolites of trinitrotoluene (TNT) have been synthesized and analysed by electron impact (EI) and chemical ionization (CI) mass spectrometry. Identification characteristics of these metabolites by their mass spectra have been determined. Differentiation of isomers is made possible by EI ions which are characteristic of the position of the methyl with regard to the nitro groups.     

Identification of bis-quaternary ammonium compounds using mild ionization mass spectrometry

Ethonium, an antimicrobial chemotherapeutic agent, was investigated by mass spectrometry (MS) under various ionization conditions: electron impact, field ionization, field desorption (FD) and fast atom ionization. FDMS was found to be the most suitable procedure for ethonium identification. Relation of the ED mass spectra to the distance between the nitrogen atoms in bis-quaternary ammonium compounds is discussed. It was shown that the most intensive ions with m/z 499, 315 in the FD mass spectra corresponded to the ethonium specific fragmentation and their occurrence in the spectra could serve as a sufficient criterion useful in qualitative and quantitative assay of the drug in the sample.     

Liquid ionization mass spectrometry of phospholipids

Several phosphatidylcholines (PC) and a phosphatidylethanolamine (PE) were subjected to liquid ionization (LI) mass spectrometry, in which a sample is ionized through energy transfer from metastable argon atoms under atmospheric pressure. Commercially available and synthesized, saturated or unsaturated fatty acid containing phospholipids and their mixtures were studied. A sample either as a concentrated chloroform-methanol solution or with glycerol (matrix) gave characteristic peaks such as MH+ and four fragment ions. One of the fragment ions (e.g., m/z 551 of PC 16:0, 16:0) containing both fatty acid residues has been commonly observed with other ionization methods such as CI, FD, and FAB, but the other fragment ions have not been observed in other mass spectra with one exception on desorption CI. Ions b and d (e.g., m/z 464 and 328, respectively, for PC 16:0, 16:0) contain one fatty acyl residue and the other ion containing the phosphorylcholine moiety appears at m/z 196 for PC. Thus the masses of the MH+ ion and these fragment ions provide useful structural information even in the case of a mixture. The ion b (e.g., m/z 488 of PC 18:0, 18:2) observed during an early period of heating was formed mainly by the loss of one acyl group at sn-1 of the glycerol backbone and thus may be used to differentiate the positional specificities of the constituent fatty acids. The temperature of the sample, however, should be controlled precisely, because it has a significant effect on the mass spectrum. The present method (LI) also provided useful information for a mixture of PC and PE.     

The identification of trimethylsilylated dipeptides with chemical ionization mass spectrometry.

The chemical ionization (CI) and electron impact (EI) mass spectra were compared for over 40 trimethylsilylated (Me₃Si) dipeptides. The dipeptides chosen had all 20 common amino acids represented at amino and carboxyl positions. The CI mass spectra of Me₃Si dipeptides typically contain three ions of high abundance used for dipeptide identification: a sequence-determining ion and two molecular weight-determining ions. The intensity of the molecular weight-determining ions relative to that of the ion that characterizes the N-terminal residue (β-cleavage ion) is greater in the CI mode than in the EI mode. Because the available intensity of the β-cleavage ion is similar in both modes, use of the CI mode will extend the lower limit for Me₃Si dipeptide identification.     

Keto acids in tissues and biological fluids: O-t-butyldimethylsilyl quinoxalinols as derivatives for sensitive gas chromatographic/mass spectrometric determination

Quinoxalinol t-butyldimethylsilyl ethers were prepared from three branched-chain and from two aliphatic unbranched 2-keto acids. The electron impact (EI) mass spectra display pronounced [M-57]+ ions. With 39-51% of total ion current contained within them, sensitivity is greater than on chemical ionization (CI) mass spectrometry of O-trimethylsilyl derivatives. Mass spectra and chromatographic behaviour of these novel keto acid derivatives are discussed and preliminary quantitative data from rat muscle are given.     

Haemoglobin adducts as biomarkers of exposure to tobacco-related nitrosamines

A sensitive gas chromatography/mass spectrometry (GC/MS) method was developed to measure nitrosamine-haemoglobin adducts (HPB-Hb) (4-hydroxy-3-pyridinyl-1-butanone) at trace levels in red blood cells of smoking and non-smoking mothers and their newborn babies. GC/MS methods with chemical ionization (CI) of methane reagent gas in both positive and negative ion mode as well as electron ionization (EI) were studied to determine differences in sensitivity among the various ionization methods. Detection limits using both positive and negative chemical ionization modes were found to be 30 fmol HPB, whereas detection using electron impact modes yielded a detection limit of 80 fmol HBP. In order to apply the various methods of detection to tobacco-exposed samples from human populations, we characterized adduct levels in maternal as well as paired fetal samples obtained from mothers exposed to tobacco smoke during pregnancy. Maternal samples were characterized using serum cotinine levels and were classified as non-smokers, passively smoke-exposed women, less than one pack per day smokers and greater than one pack per day smokers. Paired maternal and fetal blood samples were obtained at delivery for qualitative and qualitative analysis of nitrosamine adducts. Comparative derivatization of HPB released under alkaline hydrolysis conditions was performed using O-bis(trimethylsilyl)-trifluoroacetamide (BSTFA) and 2,3,4,5,6-pentafluorobenzoylchloride (PFBC). Both negative CI and positive CI modes of analysis were compared to the more widely accepted EI modes of mass spectrometric analysis. These results suggest that both NICI and PICI modes of detection offer a greater sensitivity of adduct characterization when compared with EI ionization techniques and that either NICI or PICI modes are preferably applicable towards the detection of human biomarker assessment of tobacco-related nitrosamines.     

Fast-atom-bombardment mass spectrometry and electron-impact direct-probe mass spectrometry in the structural analysis of oligosaccharides with special reference to the poly(N-acetyl-lactosamine) series.

A comparison has been made of positive- and negative-ion fast-atom-bombardment (FAB) and electron-impact (EI) mass spectrometry for analysis of oligosaccharides and alditols containing alternating and consecutive sequences of neutral and acetamido sugars. Among these were novel chemically synthesized tetrasaccharides with Ii antigen activities. FAB ionization has the advantage that it is applicable to non-derivatized oligosaccharides and it can determine Mr. However, the abundance of fragment ions providing structural information and the amount of material required for analysis (1-50 nmol) varied from sample to sample. In contrast, EI mass spectrometry of 5 nmol of permethylated or peracetylated oligosaccharides reliably gives all the fragment ions formed by cleavage across the glycosidic bonds.     

Characterization of 2,7-anhydro-N-acetylneuraminic acid in human wet cerumen

A molecular species of sialic acid was isolated in a free form from cerumen of the wet type, but not of the dry type, by an ion-exchange column chromatography and preparative high-performance liquid chromatography. Structural analysis of this sialic acid was performed by gas-liquid chromatography/mass spectrometry with chemical ionization (CI) and electron ionization (EI). In the CI mass spectra, the protonated molecular ion of the trimethylsilyl derivative was observed at m/z 580. and that of the methyl ester-trimethylsilyl derivative was at m/z 522. In the EI mass spectrum, the methyl ester-trimethylsilyl derivative gave characteristic ions at m/z 506, 462, 418, 416, 328, 316, 238, 228, 205, 186, and 173. This mass spectrum was identical with that of 2,7-anhydro-N-acetylneuraminic acid, which was reported by Lifely and Cottee (Carbohydr. Res. 107, 187-197, 1982) as the mass spectrum of a by-product prepared from N-acetylneuraminic acid by methanolysis. These results indicate that the compound in the wet cerumen is 2,7-anhydro-N-acetylneuraminic acid. Since this sialic acid species could not be detected in cerumens of the dry type, its formation in the wet type may be controlled by an autosomal dominant gene.     

Chemical ionization and electron impact mass spectra of oligosaccharides derived from sphingoglycolipids

Chemical ionization (CI) mass spectra with isobutane and ammonia for the oligosaccharides obtained from sphingoglycolipids were compared with their electron impact (EI) mass spectra. The oligosaccahride moieties were liberated from the parent glycolipids and were further reduced with sodium borohydride. They were analyzed as their permethyl peracetyl and pertrimethylsilyl derivatives. In the CI spectra, peaks corresponding to QM+ and/or [M-59]+ were observed in all of the peracetylated oligosaccharides examined. In CI with ammonia as the reagent, H+ was transferred to nitrogen-containing saccharides to produce [MH]+ and NH4 was transferred to nitrogen-free saccharides to yield [M+NH4]+ as QM+. Non-reducing ends yielded very intense peaks in CI spectra. On the other hand, the reduced end, glucitol, produced rather prominent peaks in EI spectra. Fragment ions due to cleavage of glycosidic bonds were major ones under the CI conditions, and they could be used for elucidating the sugar sequence in the oligosaccharides. An additional characteristic feature in the CI spectra was that ions due to scission of hexosaminyl glycosidic linkages were observed with very high intensities.     

Mass spectrometric localization of carbon-carbon double bonds: A critical review of recent methods

Current methods are reviewed for determining the position of double bonds in fatty acids, and other unsaturated organic compounds, using mass spectrometry. ‘On-site’ and ‘remote-site’ derivatization methods are described, and their advantages and disadvantages for mass spectrometric analysis discussed. Chemical transformation of double bonds by methoxylation, silyloxylation or deuteration, together with electron impact (EI), chemical ionization (CI) or collisionally induced decomposition (CID) techniques in combination with fast atom bombardment (FAB) or CI, are found to be most suitable for polyunsaturated fatty acids (PUFA): for the analysis of less unsaturated compounds on a submicrogram scale those methods are most promising which either do not involve derivatization of the double bonds, or give derivatives in quantitative yields. Effects of mass spectrometer geometry and operating conditions are also considered.     

The use of soft-ionization mass-spectrometry in biochemistry

Basic principles of mass spectrometry (MS) and methods of ionization are described. Methodological aspects of field ionization (FI) and field desorption (FD) MS are considered in detail. Examples are given demonstrating application of FI and FD MS as an analytical tool for structure analysis and identification of mono-, di- and oligosaccharides, nucleic acid bases, nucleosides, nucleotides, oligonucleotides, biomacromolecules (DNA, polysaccharides), microorganisms, metals in biological tissues and liquids, drugs (in particular, organophosphoric compounds) and their metabolites. The possibilities of fast atom bombardment MS in the investigation of dGuo and DNA alkylation by thiophosphamide are demonstrated.     

Evidence for the contribution of humic substances to conditioning films from natural waters

The presence of humic substances in conditioning films deposited on solid surfaces from natural waters was investigated using electron impact (EI), chemical ionization (CI) and secondary ion time-of-flight mass spectrometry (TOFSIMS). EI and CI spectra of a freshwater sample from a pond in Centennial Park, Sydney, Australia, showed a high degree of similarity with spectra of humic acids purchased from Fluka and Sigma as well as with reference humic acid and fulvic acid from the International Humic Substances Society, suggesting that most of the organic matter in the pond water was of humic origin. All the complex electron impact mass spectra feature series of high-intensity ions separated by 14 Da or 18 Da, which can be attributed to CH(2) and OH(2) respectively. Thermal desorption profiles of all samples generated by EI and CI were qualitatively similar. The secondary desorption peaks were less well-defined in CI compared to EI. Positive ion thermal desorption profiles displayed a two-step ionisation, with a sharp and well-defined initial desorption peak at t～50s, followed by a broader desorption peak with a maximum intensity at t ～ 100 s post-heating. The Centennial Park natural organic matter (NOM) differed from the other humic fractions in having two additional broad desorption peaks between the two described previously, and a less-defined initial peak. Infrared spectroscopy showed that proteinaceous matter in the lake water was insignificant in comparison with functional groups indicative of humic substances. TOFSIMS characterization showed almost identical spectra for Aldrich humic acid and Centennial Park NOM in the high mass region of 2000 Da to 3000 Da. Each spectrum contains approximately 25 groups of ion peaks, separated by 74 Da from group to group. Each group is composed of 6 or 7 individual peaks. The spectral features are consistent with a macromolecular structure of humic acid where aromatic rings are joined to the macrostructure via aliphatic spacer molecules.     

Characterization of betaines using electrospray MS/MS

Betaines are an important class of naturally occurring compounds that function as compatible solutes or osmoprotectants. Because of the permanent positive charge on the quaternary ammonium moiety, mass spectrometric analysis has been approached by desorption methods, including fast atom bombardment and plasma desorption mass spectrometry. Here we show that electrospray ionization MS gives comparable results to plasma desorption MS for a range of authentic betaine standards and betaines purified from plant extracts by ion exchange chromatography. A distinct advantage of electrospray ionization MS over plasma desorption MS is the capability of obtaining product ion spectra via MS/MS of selected parent ions, and hence structural information to discriminate between ions of identical mass.     

Isolation and identification of 1(3),2-diacylglyceryl-(3)-O-4'-(N,N,N-trimethyl)homoserine from the soil amoeba, Acanthamoeba castellanii

A polar lipid accounting for 12.5% of the total lipid nitrogen has been isolated from the protozoan Acanthamoeba castellanii. On the basis of thin-layer chromatography and mass spectral analysis, the lipid has been identified as diacylglyceryltrimethylhomoserine (DGTS). Fast atom bombardment (FAB) mass spectra of DGTS are reported for the first time and are compared to the FAB mass spectra of phosphatidylcholines and the electron ionization (EI) and field desorption (FD) mass spectra of DGTS. Gas-liquid chromatographic-mass spectrometric (GLC-MS) analysis of the acyl chain composition of this lipid has shown that 87.5% consists of cis-9-octadecenoic acid. Plasma membrane isolated from this organism has shown that labeled DGTS appears in the plasma membrane but is not enriched in this fraction. DGTS has been isolated previously only from a limited number of green plants and one species of fungus. Identification of this lipid in Acanthamoeba indicates that this lipid is distributed among a diverse group of lower eucaryotes.     

The electron impact, chemical ionization and fast atom bombardment positive ion mass spectra of 1,2-bis(sulfonyl)methylhydrazines.

A series of bis(sulfonyl)-1-methylhydrazines were analyzed by positive ion electron impact (EI), chemical ionization (CI) and fast atom bombardment (FAB) mass spectrometry. Since these compounds showed activity against the L1210 leukemia, an understanding of their mass spectral behavior is important should the structural characterization of metabolites be required. FAB proved to be the most useful technique, generally providing abundant protonated molecule ion peaks, in contrast to the weak peaks observed with CI (ammonia or isobutane) and the total absence of molecular ion peaks in the EI mass spectra. In addition, utilizing FAB eliminated the problem of thermal decomposition, which was very difficult to control under EI and CI experimental conditions. Fragments observed in FAB and CI mass spectra were consistent with protonation at the methyl-bearing nitrogen. One can locate the R1 and R2 moieties relative to the methyl-bearing nitrogen in FAB and CI by assigning that nitrogen as the site of protonation, with subsequent elimination of R2SO2H.     

Electrohydrodynamic ionization mass spectrometry of biochemical materials

Electrohydrodynamic ionization mass spectrometry has been applied to a range of biochemical materials dissolved in glycerol with NaI as electrolyte. Sugars (glucose, sucrose, raffinose), nucleosides (adenosine, thymidine, uridine), a tripeptide (glutathione) and an aminocyclitol antibiotic (neomycin) have been analyzed. Unambiguous analysis of a multicomponent solution has been demonstrated. All samples yielded several quasimolecular ions involving either proton or cation attachment to clusters of sample and/or solvent molecules. Unlike other techniques such as field desorption, electrohydrodynamic ionization is not observed to cause fragmentation of sample molecules. The mass spectrometer was operated so as to analyze only those ion clusters which had not undergone decomposition processes; under these conditions, most materials are ionized with similar efficiencies if the total abundance of all characteristic quasimolecular ions is considered. Information regarding the amino acid sequence of glutathione was obtained by thermal pretreatment of the glycerol solution before mass analysis. Positive and negative ion spectra give complementary information which can resolve potential ambiguities regarding the exact composition of quasimolecular ions. Electrohydrodynamic ionization mass spectrometry should be applicable to materials which cannot be ionized by other methods.     

Negative ion ammonia chemical ionization and electron impact ionization mass spectrometric analysis of steryl fatty acyl esters

Synthesis of steryl palmitates, varied in the nature of the steryl moiety, provided model compounds for investigation of the mass spectrometric behavior of steryl long-chain fatty acyl esters. The structure of the steryl moiety was varied according to: (i) position and degree of unsaturation in the steroid nucleus and C-17 side-chain, (ii) position and degree of methylation, (iii) presence or absence of a 9 beta, 19-cyclopropane ring. Compounds were chosen so as to be representative of biochemically important steryl esters. Electron impact (EI) behavior of steryl palmitate esters closely resembles that of their short-chain (e.g. acetate) counterparts. M+.ions were generally weak or absent and the major high mass ions arose from characteristic fragmentations of the steroid nucleus following loss of the acyl moiety ([M-RCO2H]+.). Fragment ions characteristic of the acyl moiety were lacking. Negative ion chemical ionization (NICI) using ammonia as reagent gas, on the other hand, afforded spectra containing characteristic fragment ions [RCO2]-, [RCO2-18]-, and [RCO2-19]- from which the nature of the fatty acyl moiety can be readily deduced. Hence, NICI and EI provide complementary means of ionization for the mass spectrometric determination of structures of steryl esters.     

Protein cross-links: universal isolation and characterization by isotopic derivatization and electrospray ionization mass spectrometry.

A general method of unequivocally identifying and obtaining sequence information on cross-linked peptides derived by proteolytic digestion of cross-linked proteins has been developed. The method is based on isotopic labeling of alpha-amino groups with 2, 4-dinitrofluorobenzene (DNFB) coupled with electrospray ionization mass spectrometry. Proteins containing covalent cross-link(s) are reductively methylated to convert lysine residues to dimethyl lysine. The methylated protein is partially hydrolyzed and the liberated alpha-amino termini are derivatized with an equimolar mixture of DNFB and [(2)H(3)]DNFB. Dinitrophenyl (DNP)-labeled peptides may be fractionated into mono- and bis-DNP pools by chromatography on phenyl media. The bis-DNP peptides are further separated by reverse-phase HPLC and analyzed by electrospray ionization mass spectrometry. The molecular ions of cross-linked peptides are unambiguously identified as 1:2:1 triplets in the mass spectrum resulting from the binomial distribution of isotopic label in the bis-DNP derivative. Sequence information can be elucidated from the unique product ion patterns which are generated from in-source fragmentation at an elevated cone voltage. Analysis of the disulfide cross-linked peptide (VTCG)(2) was undertaken as a proof of concept and the generality of the method was demonstrated by isolating and sequencing the isopeptide bond of polyubiquitin.     

Characterization of glycosphingolipids by supercritical fluid chromatography-mass spectrometry

Gangliosides have been characterized by supercritical fluid chromatography-chemical ionization mass spectrometry (SFC-CIMS) as permethyl and pertrimethylsilyl derivatives, using carbon dioxide as the SFC mobile phase and CI reagent gas. Ganglioside classes and ceramide heterogeneity within each class are well resolved by SFC. Direct SFC-interfacing allows the analytical manipulations of single-ion monitoring, total-ion plots, background subtraction, library searches, and spectral reconstruction algorithms. Addition of ammonia to the CI ion chamber (NH3 as a CI reagent gas) yields abundant molecular-weight-related ions, (MH)+ and (MNH4)+ from analyte derivatives. Substitution of methanol for ammonia yields considerable parent-ion fragmentation, providing structural information on carbohydrate sequence, fatty acid, and sphingoid components. Under these latter conditions a unique alpha-cleavage fragment is observed which differentiates fatty acid from sphingosine heterogeneity. For ganglioside samples, the carboxyl group of neuraminyl residue(s) have been esterified with pentafluorobenzyl bromide and the products analyzed by negative ion chemical ionization MS. This modification improves chemical selectivity and greatly enhances detecting sensitivity. These "soft" ionization conditions provide abundant molecular-weight-related anions for collision-induced dissociation and subpicogram detection.