Comparative study of acidic glycosphingolipids by field desorption and secondary ion mass spectrometry

Acidic glycosphingolipids were analyzed by field desorption (FD-MS) and secondary ion mass spectrometry (SI-MS) using the primary ion Xe+ with a glycerol matrix. In the analysis of underivatized gangliosides by FD-MS, the fragment corresponding to the asialo residue resulting from the cationized cluster ion (M + Na)+ was the base peak, and ions due to cleavage at the glycosidic linkages were detected, as in the neutral glycosphingolipids. In the case of sulfatide, the ceramide fragment showed the highest intensity in the spectrum. In SI-MS spectra of acidic glycosphingolipids, (M + Na)+, (M + 2Na-H)+, and (M + K)+ were continuously detected as relatively high intensity ions during analysis of gangliosides and sulfatide. Other ions were mostly similar to those obtained by FD-MS. In FD-MS spectra of permethylated gangliosides, the cationized molecular ion (M + Na)+ was the base peak, and fragment ions due to asialo gangliosides were prominent. Other peaks were hard to detect. In SI-MS, molecular ions (M + H)+ and (M + H-32)+ and other ions due to cleavage of the glycosidic linkages were clearly detected. In this case, the sensitivity was greatly improved. Ions due to the non reducing end sugars were clearly detected, because of the relatively low intensity of ion peaks due to the glycerol matrix. It is concluded that the combination with FD-MS and SI-MS is particularly useful for the determination of molecular weight, sugar sequence and ceramide structure with sample amounting to only a few micrograms order.     

Rapid characterization and identification of steroidal alkaloids in Sarcococca coriacea using liquid chromatography coupled with electrospray ionization quadropole time-of-flight mass spectrometry

Rapid characterization of 23 pregnane-type steroidal alkaloids was studied using a positive ion electrospray ionization quadropole time-of-flight mass spectrometry (ESI-QqTOF-MS/MS) hybrid instrument. ESI-QqTOF-MS (positive ion mode) showed the presence of the protonated molecules [M+H](+) which through low-energy collision-induced dissociation tandem mass spectrometric (CID-MS/MS) analysis showed the characteristic loss of dimethylamine moiety [M+H-45](+) followed by the sequential lossess of attached substituents. Steroidal alkaloids having tigloyl or senecioyl group at C-3 produced diagnostic fragment ions at m/z 100 and 83. Our study also demonstrates the influence of unsaturation, and number and nature of substitutents on product ion abundance and fragment ions. Moreover, the generalization of the fragmentation pattern was linked with the structural features in steroidal skeleton. This strategy was successfully applied in LC-ESI-QqTOF-MS/MS analysis of Sarcococca coriacea extract to investigate and characterize pregnane-type steroidal alkaloids in complex mixture.     

Generation of hydroxyeicosatetraenoic acids by human inflammatory cells: analysis by thermospray liquid chromatography-mass spectrometry

Arachidonic acid was converted to a series of hydroxyeicosatetraenoic acids (HETEs) by mixed human inflammatory cells following stimulation with the calcium ionophore A23187. HETEs were purified by a simple one-step extraction procedure followed by HPLC. The HPLC was coupled to a Finnigan quadrupole mass spectrometer using the now commercially available thermospray liquid chromatography-mass spectrometry interface. The HPLC eluant was monitored 'on line' by the mass spectrometer. Soft ionisation occurs, generating intense molecular ion species in the negative ion mode (M - H-:m/z 319) for each of the isomeric HETEs. The (M + H+ - H2O) ion at m/z 303 is the major species in the positive ion spectra of HETEs. Mass spectra were obtained on-line post-HPLC for HETEs formed by the human cells, and the HPLC-MS profile compared with that obtained from standards; species corresponding to the 11-, 9- and 5-HETEs were observed.     

Identification of individual steroids in biological matrices by mass-analyzed ion kinetic energy spectrometry.

Individual steroids can be distinguished by their mass-analyzed ion kinetic energy (MIKE) spectra. These spectra are taken for the protonated compounds generated by chemical ionization and they yield characteristic fragmentation patterns for different steroids. Isomeric steroids can be differentiated by their MIKE spectra. In some cases this can also be achieved by examining a single ionic reaction rather than the entire spectrum. For example, protonated dehydroepiandrosterone undergoes spontaneous elimination of water while its isomer, testosterone undergoes this reaction with a lower cross-section and then only when excited by collision with target gas. Mixtures of steroids can be analyzed qualitatively. This is illustrated by the analysis of birth control pills (Ovral) for ethynylestradiol and norgestrol. Analysis of urine specimens for particular steroids without pretreatment or preconcentration is possible in some cases.     

Analysis of oxidative warfarin metabolites by thermospray high-performance liquid chromatography/mass spectrometry

Oxidative metabolites of the anticoagulant, warfarin [4-hydroxy-3-(3-oxo-1-phenylbutyl)-2H-1-benzopyran-2-one], produced by the actions of cytochromes P450 were analyzed by thermospray high-performance liquid chromatography/mass spectrometry. Warfarin, dehydrowarfarin, and the 6-, 7-, 8-, and 4'-hydroxy derivatives of warfarin were found to ionize well by the thermospray process in the presence of ammonium acetate. Thermospray mass spectra of these compounds were generally dominated by the protonated molecule, (M + H)+, and ions formed by the loss of water from the protonated molecule, (M + H - H2O)+. Fragment ions arising from the hydroxycoumarin, benzylhydroxycoumarin, and phenylbutanone portions of the molecules were observed, and the relative intensity of these fragment ions was greatly increased with filament ionization and application of a high repeller potential (100-130 V). Selected-ion monitoring of the (M + H)+ and (M + H - H2O)+ ions provided sensitivities for these compounds in the 2 to 10 ng range. A method employing thermospray HPLC/MS with selected-ion monitoring and internal standard quantitation for the analysis of the oxidative metabolites of warfarin is described.     

Study of the structure of anthracycline antibiotics by ERIAD mass spectrometry

Fragmentation of antibiotics daunorubicin, carminomycin, doxorubicin and their semisynthetic analogues under conditions of the new mass spectrometry method ERIAD is discussed. Signals of protonated molecular ion (M + H)+ and ions of fragments are present in all the mass spectra. The results are compared with literary data obtained by means of other (EI and FAB MS) mass spectrometry methods.     

Collisionally induced fragmentation of protonated oligoalanines and oligoglycines.

In a hybrid instrument under minimal multiple-collision conditions, the collision-induced fragmentation of the [M + H]+ ions of tetraalanine and tetraglycine are dominated by the gamma 2 fragment, in distinction to the fragmentation of the [M + H]+ ions of hexa- and octaalanine and -glycine; these latter fragmentations are instead a distribution of b and y ions, and to a lesser extent a ions. This difference may be rationalized on the basis of control of the fragmentation by the most basic site in the peptide, which may be identified by taking internal hydrogen bonding into account. On increasing the collision energy from 10 to 150 eV, a, b and y ions of lower mass appear; and in several cases a peak due to a smaller b ion becomes the base peak. The ion distribution in the spectra of these protonated peptides serves as a baseline from which the effects of conformation on side-group rearrangements and other fragmentations may be explored.     

Mass spectrometric identification and quantification of glycosyl flavonoids, including dihydrochalcones with neutral loss scan mode

We developed a strategy for determination and quantification of glycosyl flavonoids using liquid chromatography-triple quadrupole mass spectrometry with neutral loss scan at 15 and 30eV collision energy in the positive ion mode. The fragmentation patterns of glycosyl flavonoids at 15 and 30eV showed that fragmentation of sugar moiety depended on the type of glycosidic bond to aglycone, the site of C-glycosylation, and the type of aglycone. C-Glycosyl dihydrochalcones especially stood out because they produced [M+H-162](+) even at 15eV such as O-glycoside in spite of C-glycoside. C-Glycosides were classified according to (i) the intensity ratio A of [M+H-150](+) to [M+H-120](+) at 30eV and (ii) the intensity ratio B of [M+H-120](+) at 15eV to one at 30eV. The 8-C-glycosides were A<1 and B<1, the 6-C-glycosides were A>1 and B<1, and the C-glycosyl dihydrochalcones were A>1 and B>1. Therefore, the intensity ratios of the neutral loss scan of 120 and 150Da at 30eV and those of 120, 162, and 308Da at 15eV allowed sequential distinction among these three types of C-glycosides as well as between O- and C-glycosides. Our method was applied for analysis of Rooibos tea, and the identified glycosides could be quantified specifically by the selected reaction monitoring method.     

New approach for characterization of lysosulfatide by TLC, fast atom bombardment mass spectrometry and NMR spectroscopy

Thin layer chromatography of lysosulfatide showed anomalous Rf-values in contrast with such lysosphingolipids as glucopsychosine and galactopsychosine with neutral, acidic, and alkaline developing solvents. This was thought to be due to the presence of oppositely charged sulfate and amino groups in the lysosulfatide. In the negative mode of fast atom bombardment mass spectrometry, the lysosulfatide showed the pseudo molecular ion (M-H)- peak at m/z 540 and sulfate ion peak at m/z 97, whereas in the positive mode, it showed not only the pseudo molecular ion (M+H)+ peak at m/z 542, but also the major peaks of protonated psychosine at m/z 462 and fragment ions of dehydrated sphingosine at m/z 282 and 264, 13C-NMR signals of all carbons of lysosulfatide were determined by using distortionless enhancement by polarization transfer. The difference in chemical shifts of ring carbons of galactose residue between lysosulfatide and galactopsychosine was largest at C-3 (downfield shift), thereby indicating the location of the sulfate group to be at C-3 of galactose. This conclusion is supported by the 1H-NMR spectra of the lysosulfatide and galactopsychosine. Thus, the chemical structure of lysosulfatide was confirmed by fast atom bombardment mass spectrometry and 13C- and 1H-NMR spectroscopy. Furthermore, 13C-NMR signals of C-1 to C-5 of the sphingosine moiety showed significantly different chemical shifts between the lysosulfatide and galactopsychosine. These differences suggested that C-1 to C-5 of sphingosine might be influenced by intramolecular or intermolecular interaction between the sulfate group of the galactose residue and the amino group of sphingosine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fast atom bombardment and tandem mass spectrometry for structure determination of steroid and flavonoid glycosides

The combination of fast atom bombardment (FAB) and tandem mass spectrometry (MS-MS) was tested for its applicability to generate useful structural information for steroid and flavonoid glycosides. The following compounds were investigated: quercetin, myricitrin, apigetrin, fraxin, rutin, neohesperidin, hesperidin, naringin, apiin, cymarin, digoxin, digitoxin, xanthorhamnin, and frangulin. Upon FAB, the sample molecules are desorbed as (M + H)+, (M - H)-, or as (M + Na)+ or (M + K)+. Collisional activation of (M + H)+ or (M - H)- ions in the MS-MS experiment leads to sequential losses of glycoside moieties in a manner which permits the sequence of glycosides to be established. Some glycosides occur as mixtures of homologs. Proper interpretation of the MS-MS or collisional activation decomposition spectra often allows the homology to be located. In addition to the simple and highly selective fragmentations observed in this combined experiment, FAB and MS-MS also remove interference caused by the ubiquitous matrix ions which are desorbed by FAB.     

Fast atom bombardment and collisional activation mass spectrometry of retinyl phosphate mannose synthesized by liver membranes

Fast atom bombardment (FAB) and collisional activation dissociation (CAD) mass-analysed ion kinetic energy (MIKE) spectra have confirmed the structures of retinyl phosphate (Ret-P), retinyl phosphate mannose (Ret-P-Man) and guanosine 5'-diphospho-D-mannose (GDP-Man). Ret-P-Man was made in vitro while Ret-P and GDP-Man were chemically synthesized. Positive ion FAB mass spectrometry of Ret-P showed an observable short-lived spectrum with a mass ion at m/z 367 [M + H]+, and a major fragment ion at m/z 269 [M + H - H3PO4]+. Negative ion FAB mass spectrometry of Ret-P showed a strong stable spectrum with a parent ion at m/z 365 [M - H]-, a glycerol (G) adduct ion at m/z 457 [M - H + G]- and a dimer ion at m/z 731 [2M - H]-. GDP-Man showed an intense spectrum with parent ion at m/z 604 [M - H]- and cationized species at m/z 626 [M + Na - 2H]- and 648 [M + 2Na - 3H]-. Negative ion FAB mass spectrometry of Ret-P-Man showed a parent ion at m/z 527 [M - H]- and a fragment ion at m/z 259 [C6H12PO9]-. The CAD-MIKE spectra showed structurally significant fragment ions at m/z 442 and 361 for the [M - H]- ion of GDP-Man, and at m/z 509, 406, 364 and 241 for the [M - H]- ion of Ret-P-Man. FAB and CAD-MIKE spectra have been applied successfully to confirm the structure of Ret-P-Man made in vitro from Ret-P and GDP-Man.     

Laser desorption ionisation-time of flight mass spectrometry of the tolyporphins, bioactive metabolites from the cyanobacterium Tolypothrix nodosa

Introduction – The tolyporphins are metabolites isolated from the cyanobacterium Tolypothrix nodosa, comprising a porphyrin‐like macrocycle with C‐glycoside, hydroxide or acetate substituents. Previous studies of porphyrins by MALDI/LDI‐TOF MS indicate that strong radical cations and anions are usually observed in the parent spectra with little fragmentation of the macrocycle. The spectra of the tolyporphins were obtained and trends in the series utilised to partially characterise two new analogues. Objective – To examine tolyporphins by LDI‐TOF MS and utilise trends observed to partially characterise two new analogues. Methodology – The tolyporphins were analysed by LDI‐TOF MS in positive and negative ion mode and by a post source decay method (LIFT) in positive ion mode. Tolyporphin A was also analysed by MALDI‐TOF MS for comparison. Results were analysed and used to obtain structural information on two new analogues. Results and Discussion – The resulting spectra generally contained intense radical cations or anions, with little fragmentation of the macrocyclic core or the C‐glycosides observed. These results are consistent with previous studies of porphyrins. Major fragment ions observed in LIFT spectra yielded key structural information. An inseparable mixture of two tolyporphins was also examined. Analysis of the LIFT spectrum of the parent ion resulted in the postulation of structures of these two new analogues. Conclusions – Tolyporphins yield LDI‐TOF mass spectra somewhat analogous to those of porphyrins; furthermore, the substituents fragment in a characteristic manner permitting partial characterisation of the new analogues tolyporphins L and M by comparison of their LDI‐TOF mass spectra with those of the known analogues. Copyright © 2011 John Wiley & Sons, Ltd.     

Positive-negative, chemical-ionization, direct exposure mass spectrometry of underivatized prostaglandins

Nine underivatized prostaglandins were examined using direct exposure, ammonia, chemical-ionization, pulsed positive-negative ion mass spectrometry. The positive ion spectra were characterized by (M+18)+ ion adducts. The negative ion spectra were characterized by ions which depended upon the functionality present in the cyclopentane ring system (acetal for TXB2). The E and D series prostaglandins gave (M-18)- as the major negative ion, while the F series and TXB2 were characterized by negative ions corresponding to (M-1)-, and PGA2 by the parent (M)- ion. Prostaglandin 6-keto-PGF1 alpha was anomalous in this respect showing apparent dehydration, interpreted as an overall (M-18+1)+ and (M-18-1)- in the positive and negative ion spectra, respectively. All major ion types were shown to give essentially a linear response with respect to concentration in the 10-1000 ng range. Although these initial studies were conducted under ideal conditions, it would appear that direct chemical ionization techniques show promise for providing direct structural information on prostaglandins without the need for prior chemical derivatization.     

Structural studies of gangliosides by fast atom bombardment ionization, low-energy collision-activated dissociation, and tandem mass spectrometry

Negative ion fast atom bombardment, low-energy collision-activated dissociation, and tandem mass spectrometry techniques were applied for the structural elucidation of gangliosides. The mass spectra were simplified by selecting a single molecular ion or fragment ion in the analysis of mixtures, and interference by background signals from the liquid matrix could be avoided. Introduction of collision-activated dissociation produced abundant fragment ions convenient for structural analysis. In the daughter scan mode, ions were produced by cleavage of the glycosidic bonds, and not by cleavage at the sugar ring. These ions all contain ceramide moieties, except the sialic acid fragment ion. In the parent scan mode, product ions resulting from cleavage at the sugar ring were detected beside the ions resulting from cleavage at the glycosidic bonds, and ions of oligosaccharide fragments were also detected. In parent scan mode spectra of gangliosides based on the sialic acid ion, all ions contained a sialic acid residue, and the observed ions were similar to those obtained in the high-energy collision-activated dissociation daughter scan mode. These results indicate the usefulness of low-energy collision-activated dissociation tandem mass spectrometry in the daughter and parent scan modes for the analysis of ganglioside structure, in combination with fast atom bombardment mass spectrometry and high-energy collision-activated dissociation mass spectrometry.     

Combined assay for phenacetin and paracetamol in plasma using capillary column gas chromatography—negative-ion mass spectrometry

A gas chromatographic—mass spectrometric assay has been developed for the measurement of phenacetin and its major metabolite paracetamol in plasma. Phenacetin and unconjugated paracetamol are analysed in a single chromatographic run while total paracetamol is measured separately after enzymatic hydrolysis. The two compounds, and the deuterated analogues used as internal standards, are analysed as their trifluoroacetyl derivatives and the mass spectrometer is operated in the electron-capture negative-ion chemical ionisation mode. The negative-ion mass spectra of the derivatives contain fragment ions, formed by loss of an acetyl group from the respective molecular ions, which are the base peaks in the spectra. When these ions are specifically monitored, amounts of derivative equivalent to 1 pg of parent compound can be detected. This allowed the development of an assay for phenacetin, unconjugated paracetamol and total paracetamol in plasma having a precision of 2.6, 1.4 and 2.4%, respectively, and preliminary results for a subject given a 100-mg oral dose of phenacetin are reported.     

Chemical-ionization mass spectrometry of carbohydrates: behavior of the antibiotic celesticetin under various conditions of ionization

The chemical-ionization mass spectrum of the polyfunctional carbohydrate antibiotic, celesticetin, is remarkably simple, in contrast to its electron-impact mass spectrum. With ammonia as the ionizing gas the protonated molecular ion is the principal species, and simple fragmentation modes reflect eleavage between principal moietics of the molecule. Substantial modifications of the fragmentation pathway are observed when isobutane is used as the ionizing gas. The different pathways of fragmentation according to the mode of ionization are interpreted in terms of differential reactivity of various heteroatomic centers in the molecule toward each of the ionizing agents. Use of a combination of ionizing modes may provide a useful general method for identification on a micro scale of complex carbohydrates isolated from fermentation or other mixtures.     

Identification of trichothecenes by thermospray, plasmaspray and dynamic fast-atom bombardment liquid chromatography—mass spectrometry

Thermospray, plasmaspray and dynamic fast-atom bombardment liquid chromatography—mass spectrometry are compared for the identification of six trichothecenes. Thermospray spectra of the trichothecenes exhibit only a very abundant ammonium adduct ion. Plasmaspray, which provides a more energetic ionization process than thermospray, produces some fragment ions in addition to an abundant ammonium adduct ion. The spectra obtained by dynamic fast-atom bombardment exhibit a protonated molecule, a glycerol adduct ion and numerous fragment ions formed by the losses of functional groups as neutrals in various combinations. Thermospray and plasmaspray are suitable only for monitoring of the trichothecenes, whereas dynamic fast-atom bombardment is suitable for monitoring and for structure characterization.     

Field desorption mass spectrometry. II. Potassium cationization field desorption mass spectrometry of some penta- and hexapeptides derived from substance P

In this article we present preliminary results of the application of potassium cationized field desorption mass spectrometry as an additional technique for the elucidation of structure and evaluation of purity of oligopeptides such as C-terminal penta- and hexapeptide analogs of substance P. In the resultant mass spectra both a protonated and a cationized molecular ion, MH+ and MK+ respectively, were observed. The m/z values of the two peaks were in agreement with the calculated molecular weights. The ratio between the relative abundancies of these ions (MH+/MK+) was found to be characteristic of the particular peptide and thus useful in the assessment of their purity. Among the 13 peptides studied, only two gave pyrolytic fragmentation leading to a more complex spectra.     

Determination of 1-O-acyl-2-acetyl-sn-glyceryl-3-phosphorylcholine,platelet-activating factor and related phospholipids in biological samples by high-performance liquid chromatography-tandem mass spectrometry

Combining normal-phase HPLC separation and tandem mass spectrometric detection, using an ion-spray HPLC-MS interface, a quantitative method for acyl-platelet activating factor (acyl-PAF), platelet-activating factor (PAF) and related phospholipids was developed. Mass spectra, positive ions, showed intense [M+H]⁺ ions; collision-induced dissociation of protonated molecular ions gave characteristic daughter ions corresponding to the polar head. Detection limits of 0.1–0.3 ng injected were obtained by multiple reaction monitoring. Samples of human endothelial cells treated with compounds modulating the levels of acyl-PAF and PAF have been analyzed by the present technique, proving that this approach is suitable for biochemical studies.     

A convenient, unified scheme for the differential extraction of conjugated and unconjugated serum C19 steroids on Sep-Pak C18-cartridges

In order to conveniently and rapidly isolate by group both conjugated and unconjugated serum androgens, a scheme has been devised for their differential extraction from commercially available, disposable octadecylsilane cartridges (Sep-Pak C18). Using added radioactive steroid standards and detection of endogenous serum steroids by group-specific enzymatic assays, the quantitative recovery of steroid glucuronides and sulfates in the 47% methanol fraction and of unconjugated steroids in the 100% methanol fraction was observed. Maximum recovery of serum protein-bound steroids (e.g. testosterone) was achieved with serum denatured by urea and heat. In order to separate glucuronides from sulfates, sequential hydrolysis of the conjugated fraction (47% methanol) by enzymatic hydrolysis and then organic solvolysis as well as an additional Sep-Pak cartridge extraction step was required. Groups of extracted steroids may be further separated and assayed by any appropriate method(s). An application is given which employs HPLC and an enzymatic assay for 17 beta-hydroxy- and 17-oxo-steroids to provide separate profiles of unconjugated, glucuronidated, and sulfated androgens in human, male serum.