Polysulfated carbohydrates analyzed as ion-paired complexes with basic peptides and proteins using electrospray negative ionization mass spectrometry

Matrix-assisted laser desorption/ionization mass spectrometric analysis of polysulfated-derived oligosaccharides using pyrenemethylguanidine

A better understanding of the biological roles of carbohydrates requires the use of tools able to provide efficient and rapid structural information. Unfortunately, highly acidic oligomers-such as polysulfated oligosaccharides-are very challenging to characterize because of their high polarity, structural diversity, and sulfate lability. These features pose special problems for matrix-assisted laser desorption/ionization mass spectrometric (MALDI-MS) analysis because polysulfated carbohydrates exhibit poor ionization efficiency and usually do not produce any signal. The present report demonstrates how MALDI-MS can be used to derive structural and compositional information from pure and mixed fractions of polysulfated oligosaccharides. Indeed, pyrenemethylguanidine (pmg, a derivatizing agent and ionization efficiency enhancer) was used for the analysis of di- to decasaccharides, carrying from two to nine sulfate groups. The method is applied to various highly sulfated chondroitin and carrageenan oligosaccharides as well as to the analysis of mixtures of compounds. In the mass spectra, the observation of a unique pmg-complexed ladder of peaks in both ionization modes allows an easy and rapid determination of both the number of sulfate groups carried by the analyte and its molecular weight. Moreover, we have developed a software tool for the rapid and automatic structural elucidation of carrageenans based on the mass spectra obtained.

Frontal Analysis Capillary Electrophoresis Hyphenated to Electrospray Ionization Mass Spectrometry for the Characterization of the Antithrombin/Heparin Pentasaccharide Complex

The interaction of proteins with polysaccharides represents a major and challenging topic in glycobiology, since such complexes mediate fundamental biological mechanisms. A new strategy based on the hyphenation of frontal analysis capillary electrophoresis (FACE) with electrospray ionization mass spectrometry (ESIMS) is reported for the characterization of protein/carbohydrate complexes. While most of the previously reported CE-MS experiments were performed using capillary electrophoresis in zone format, we report for the first time CE-MS experiments in which CE was performed in frontal analysis (FACE-MS). We showed that the frontal mode offered a better sensitivity than zone mode and was well suited for the CE-MS coupling. This FACE-MS coupling was applied to the analysis of the complex between antithrombin and the sulfated pentasaccharide reproducing the antithrombin-binding sequence in heparin. The mixture of coincubated antithrombin and heparin pentasaccharide was continuously injected into the capillary, and the electrophoretic separation of the free and bound forms of the protein was achieved. The intact noncovalent complex antithrombin/heparin pentasaccharide was detected on-line by ESIMS in positive ionization mode and in nondenaturing sheath liquid conditions. The complex stoichiometry was determined from the mass measurement of the complex. In addition, the characterization of the sulfated pentasaccharide ligand dissociated from the complex was performed in negative ionization mode using a denaturing sheath liquid, allowing the determination of its molecular mass and sulfation features. This FACE-ESIMS strategy opens the way to ligand fishing experiments performed on heterogeneous carbohydrate mixtures and subsequent characterization of specifically bound carbohydrates.

Method for characterizing sulfated glycoproteins in a glycosylation site-specific fashion, using ion pairing and tandem mass spectrometry

Structural analysis of sulfated glycans is essential in understanding their biological significance. Here, we present a new approach to characterize sulfated glycans present on glycoproteins. The analysis is performed on glycopeptides, so information about the sulfated species is obtained in a glycosylation site-specific manner. This method employs an ion-pairing reagent to stabilize the SO3 group of the glycopeptide, allowing useful information to be obtained during MS/MS experiments. The amount of structural information obtained from (+)ESI-MS/MS of the ion-pair complexes for sulfated glycopeptides of equine thyroid stimulating hormone is compared with information obtained by (-)ESI-MS/MS of the underivatized, sulfated glycopeptides. The results indicate that this new method provides detailed insights into the sequence, branching, and type of N-glycans present, compared to analysis via (-)ESI-MS/MS.

Distinguishing phosphorylation and sulfation in carbohydrates and glycoproteins using ion-pairing and mass spectrometry

Phosphorylation and sulfation are important modifications affecting the biological properties of carbohydrates, proteins, and glycoproteins. Identification of these two functional groups facilitates the understanding of the structure/function relationship in various species. Mass spectrometry is one of the methods used to detect the presence of these two modifications in complex biological mixtures. However, phosphorylated and sulfated structures are isobaric; thus, differentiation between them in routinely used mass spectrometers is problematic. Herein, we demonstrate that these two groups can be discriminated by using ion-pairing in conjunction with MS/MS experiments. The characteristic product ions are used to successfully identify the phosphorylation and sulfation present in mono-, disaccharides, and the highly sulfated glycoprotein, ovine luteinizing hormone. This method is a robust approach to differentiate the two isobaric functional groups.

A novel mass spectrometric method to distinguish isobaric monosaccharides that are phosphorylated or sulfated using ion-pairing reagents

Phosphorylation and sulfation are two important biological modifications present in carbohydrates, proteins, and glycoproteins. Typically, sulfation and phosphorylation cause different biological responses, so differentiating these two functional groups is important for understanding structure/function relationships in proteins, carbohydrates, and metabolites. Since phosphorylated and sulfated compounds are isobaric, their discrimination is not possible in routinely utilized mass spectrometers. Thus, a novel mass spectrometric method to distinguish them has been developed. Herein, we utilize basic peptides as ion-pairing reagents to complex to phosphorylated and sulfated carbohydrates via noncovalent interactions. By performing ESI-MS/MS on the ion-pair complexes, the isobaric compounds can be distinguished. This is the first study demonstrating that ion-pairing can be used for the detection of phosphorylated compounds and the first study to use ion-pairing in conjunction with MS/MS to obtain structural information about the analytes.

On-Line Liquid Chromatography Electrospray Ionization Mass Spectrometry for the Characterization ofκ- andι-Carrageenans. Application to the Hybridι-/ν-Carrageenans

An on-line liquid chromatography electrospray ionization mass spectrometry (MS) method was developed for the characterization of polymers of kappa- (extracted from Kappaphycus alvarezii), iota-, and hybrid iota-/nu-carrageenans (both extracted from Eucheuma denticulatum) enzymatically digested with specific carrageenase enzymes. Applying either CID MS/MS or in-source fragmentation mechanisms, the results demonstrated that none of the polymers of kappa- or iota-carrageenans existed with their ideal repeating units. On the polymer of kappa-carrageenan, the nonideal structures identified consisted of iota-neocarrabiose sulfate units. On the polymer of iota-carrageenan, the nonideal structures identified consisted of the following: (i) kappa-neocarrabiose sulfate units, (ii) iota-neocarrabiose sulfate units with an additional sulfate group, and (iii) iota-neocarrabiose sulfate units with an additional sulfate and a pyruvate acetal group. For both kappa- and iota-carrageenans, the nonideal structures were randomly distributed on the polymers. The method was then applied for the characterization of a hybrid polymer of iota-/nu-carrageenans, enzymatically digested with iota-carrageenase. The results did not reveal an ideal oligosaccharide of nu-carrageenan, suggesting that the iota-carrageenase enzyme could cleave only reduced "densities" of nu-carrageenan repeating units. In addition, information about the sequence of hybrid iota-/nu-carrageenans from E. denticulatum is deduced.

Enhanced detection of sulfated glycosylation sites in glycoproteins

We demonstrate a method that enhances the mass spectral signal of mono- and disulfated glycopeptides, present in glycoproteins that contain many other nonsulfated glycoforms. This method utilizes the tripeptide Lys-Lys-Lys as an ion-pairing reagent to complex selectively to sulfated species, and enhance their ion signal. The method is applied to the analysis of glycopeptides released from the enzymatic digestion of ovine luteinizing hormone. In this analysis, a disulfated glycopeptide is identified that was previously not detectable by MS assays, and a monosulfated glycoform, present at less than 1% abundance, is identified without any separation or enrichment of these species prior to analysis. In addition to enhancing the ion signal of sulfated glycopeptides, the ion-pairing technique is useful in obtaining structural information about the sulfated species.

Competing fragmentation processes in tandem mass spectra of heparin-like glycosaminoglycans

Heparin-like glycosaminoglycans (HLGAGs) are highly sulfated, linear carbohydrates attached to proteoglycan core proteins and expressed on cell surfaces and in basement membranes. These carbohydrates bind several families of growth factors and growth factor receptors and act as coreceptors for these molecules. Tandem mass spectrometry has the potential to increase our understanding of the biological significance of HLGAG expression by providing a facile means for sequencing these molecules without the need for time-consuming total purification. The challenge for tandem mass spectrometric analysis of HLGAGs is to produce abundant ions derived via glycosidic bond cleavages while minimizing the abundances of ions produced from elimination of the fragile sulfate groups. This work describes the competing fragmentation pathways that result from dissociation of high negative charge state ions generated from HLGAGs. Glycosidic bond cleavage ion formation competes with losses of equivalents of H2SO4, resulting in complex ion patterns. For the most highly sulfated structure examined, an octasulfated tetramer, an unusual loss of charge from the precursor ion was observed, accompanied by low abundance ions originating from subsequent backbone cleavages. These results demonstrate that fragmentation processes competing with glycosidic bond cleavages are more favored for highly sulfated HLGAG ions. In conclusion, reduction of charge-charge repulsions, such as is achieved by pairing the HLGAG ions with metal cations, is necessary in order to minimize the abundances of ions derived via fragmentation processes that compete with glycosidic bond cleavages.

Mass spectrometric analysis of 7-sulfoxymethyl-12-methylbenz[a]anthracene and related electrophilic polycyclic aromatic hydrocarbon metabolites

The Meso-region theory of polycyclic aromatic hydrocarbon (PAH) carcinogenesis predicts that the development of pronounced carcinogenicity depends on the introduction of a good leaving group on alkyl side-chains attached to the exceptionally reactive meso-anthracenic or L-region positions of PAHs. Thus, the first step in carcinogenesis by methylated PAHs such as 7,12-dimethylbenz[a]anthracene (DMBA) would be the hydroxylation of the L-region methyl groups, particularly the 7-methyl group. The second would be the formation of a metabolite, e.g. a sulfate ester, which is expected to be a good leaving group capable of generating a highly reactive benzylic carbocation. 7-Hydroxymethyl-12-methylbenz[a]anthracene (7-HMBA) is a metabolite of DMBA, and sulfation of 7-HMBA to a 7-sulfoxymethyl metabolite (7-SMBA) is a known Phase II metabolic process designed to facilitate excretion, but actually enabling more destructive side-reactions. These side-reactions occur with generation of an electrophilic 7-methylene carbonium ion, and/or by in vivo halide exchange to provide neutral side-products more capable of entering cells, especially those of DMBA target tissues. Electrospray ionization mass spectrometry (MS) enabled us to visualize 7-SMBA as an intact m/z 351 conjugate anion by negative mode, and as a released m/z 255 carbonium ion by positive mode. Upon prolonged refrigeration, 7-SMBA accumulated an m/z 383 photooxide, which appeared capable of re-evolving the starting material as visualized by tandem quadrupole MS, or MS/MS. The 7-SMBA carbonium ion provided interpretable fragments when studied by fragment ion MS/MS, including those representing the loss of up to several protons. Subtle differences in this property were encountered upon perturbing 7-SMBA, either by warming it at 37 degrees C for 2 h or by substituting the initial sulfoxy group with an iodo group. Side-reactions accounting for such proton losses are proposed, and are of interest whether they occur in the mass spectrometer, in solution or both; these proposals include acidity at the 12-methyl position and cyclization between the 12-methyl group and the adjacent C-1 position. It is also suggested that such side-reactions may comprise one route to relieving steric strain arising between the 12-methyl group and the angular benzo ring of 7-SMBA.

Mass spectrometry of oligosaccharides

Glycosylation is a common post-translational modification to cell surface and extracellular matrix (ECM) proteins as well as to lipids. As a result, cells carry a dense coat of carbohydrates on their surfaces that mediates a wide variety of cell-cell and cell-matrix interactions that are crucial to development and function. Because of the historical difficulties with the analysis of complex carbohydrate structures, a detailed understanding of their roles in biology has been slow to develop. Just as mass spectrometry has proven to be the core technology behind proteomics, it stands to play a similar role in the study of functional implications of carbohydrate expression, known as glycomics. This review summarizes the state of knowledge for the mass spectrometric analysis of oligosaccharides with regard to neutral, sialylated, and sulfated compound classes. Mass spectrometric techniques for the ionization and fragmentation of oligosaccharides are discussed so as to give the reader the background to make informed decisions to solve structure-activity relations in glycomics.

Liquid Chromatography/Mass Spectrometry Sequencing Approach for Highly Sulfated Heparin-derived Oligosaccharides

Liquid chromatography/mass spectrometry (LC/MS) is applied to the analysis of complex mixtures of oligosaccharides obtained through the controlled, heparinase-catalyzed depolymerization of heparin. Reversed-phase ion-pairing chromatography, utilizing a volatile mobile phase, results in the high resolution separation of highly sulfated, heparin-derived oligosaccharides. Simultaneous detection by UV absorbance and electrospray ionization-mass spectrometry (ESI-MS) provides important structural information on the oligosaccharide components of this mixture. Highly sensitive and easily interpretable spectra were obtained through post-column addition of tributylamine in acetonitrile. High resolution mass spectrometry afforded elemental composition of many known and previously unknown heparin-derived oligosaccharides. UV in combination with MS detection led to the identification of oligosaccharides arising from the original non-reducing end (NRE) of the heparin chain. The structural identification of these oligosaccharides provided sequence from a reading frame that begins at the non-reducing terminus of the heparin chain. Interestingly, 16 NRE oligosaccharides are observed, having both an even and an odd number of saccharide residues, most of which are not predicted based on biosynthesis or known pathways of heparin catabolism. Quantification of these NRE oligosaccharides afforded a number-averaged molecular weight consistent with that expected for the pharmaceutical heparin used in this analysis. Molecular ions could be assigned for oligosaccharides as large as a tetradecasaccharide, having a mass of 4625 Da and a net charge of -32. Furthermore, MS detection was demonstrated for oligosaccharides with up to 30 saccharide units having a mass of >10000 Da and a net charge of -60.

Comprehensive strategy for chiral separations using sulfated cyclodextrins in capillary electrophoresis

This review focuses on the emerging role of sulfated cyclodextrins in the capillary electrophoretic (CE) separation of chiral analytes. Since being introduced as enantioselective agents for CE in 1995, these anionic additives have continued to demonstrate remarkable application universality. The broad spectrum of chiral compounds successfully separated using this approach includes acidic, basic, neutral, and zwitterionic species. This impressive array of analyte structures is derived from a growing diversity of compound classes including pharmaceuticals, plant extracts, biomarkers, herbicides, alkaloids, fungicides, and metal ions. Moreover, literature reports highlight the minimal optimization required to achieve a successful separation. Based on these findings, sulfated cyclodextrins appear to be well suited for the development of a more universal, comprehensive separation strategy for chiral compounds. This review explores this proposition by beginning with the structure and migration properties of sulfated cyclodextrins, using applications to highlight the separating power of this technique and ending with a pragmatic, comprehensive separation strategy.

Probing the Interactions of Phosphosulfomannans with Angiogenic Growth Factors by Surface Plasmon Resonance

The binding interactions of the phosphosulfomannan anticancer agent PI-88 (1) with the angiogenic growth factors FGF-1, FGF-2, and VEGF were studied by surface plasmon resonance (SPR) on a BIAcore 3000 biosensor. Compared with heparin, PI-88 has at least 11-fold higher affinity for FGF-1 and at least 3-fold higher affinity for VEGF, but at least 13-fold lower affinity for FGF-2. To define the structural features of PI-88 that are important for growth factor binding, several analogues, such as dephosphorylated PI-88 and a sulfated pentasaccharide, were prepared. The binding interactions of these analogues with FGF-1, FGF-2, and VEGF were similarly studied by SPR, and structure-activity relationships were determined.

Evaluation of counterions for electrospray ionization mass spectral analysis of a highly sulfated carbohydrate, sucrose octasulfate

A systematic approach was used to evaluate the electrospray ionization mass spectral (ESI-MS) analysis of sucrose octasulfate (SOS), an important pharmaceutical agent. SOS represents a model for other suffated carbohydrates, such as heparin and glycosaminoglycan-derived oligosaccharides that also are highly sulfated and pose difficult analytical problems. A survey of ammonium counterions showed that 1 degree, 2 degrees, and 3 degrees ammonium salts of SOS gave substantial fragmentation as a result of sulfate loss. In contrast, quaternary ammonium and phosphonium salts gave excellent ESI spectra, particularly in the positive ion mode. This represents the first report of the ESI-MS analysis of sulfated carbohydrates in the positive ion mode.

Analytical method of heparan sulfates using high-performance liquid chromatography turbo-ionspray ionization tandem mass spectrometry

We established a highly sensitive quantitative analytical method of heparan sulfates (HS) by LC-MS-MS. It became possible to determine the unsaturated disaccharides produced by the enzyme digestion of HS, and to perform the whole analyses on one sample within 3 min by use of a short column of CAPCELL PAK NH2 UG80 (35 mm x 2 mm I.D.). The assay method was validated and showed the satisfactory sensitivity, precision and accuracy, which enabled the quantitation up to picomol level. By employing this method, we performed the analyses of HS in mouse brain and liver, and tumor tissues of tumor-bearing mouse transplanted subcutaneously with Meth A fibrosarcoma cells. The compositions of the unsaturated disaccharide units derived from HS were found to be somewhat different among those tissues. It is assumed that the site of sulfation in HS may be controlled by certain regulatory mechanisms. The quantitative method developed in this study is believed to be a very useful method for the determination of compositional profiles of constitutive disaccharide units of tissue HS.

Detection and quantification of the sulfated disaccharides in chondroitin sulfate by electrospray tandem mass spectrometry

A new method of identifying and quantifying the disaccharide building blocks of glycosaminoglycans is introduced. The polysaccharides are subjected to an enzymatic digestion that releases the sulfated disaccharides. The disaccharides are then identified using a combination of electrospray ionization mass spectrometry and tandem mass spectrometry. Quantification of the isomeric disaccharides is also achieved by tandem mass spectrometry, using a recently developed methodology which quantifies mixtures of isomers without the use of chromatography or prior separation. Using mass spectrometry to characterize the components of glycosaminoglycans significantly reduces both sample consumption and analysis time of traditional methods.

Synthesis and analytical characterization of the sodium salt of heptakis(2-O-methyl-3,6-di-O-sulfo)cyclomaltoheptaose, a chiral resolving agent candidate for capillary electrophoresis

A pure, single isomer, strong electrolyte chiral resolving agent candidate for capillary electrophoresis, the sodium salt of heptakis(2-O-methyl-3,6-di-O-sulfo)cyclomaltoheptaose has been synthesized on the 100-g scale, in greater than 97% purity, through heptakis(2,6-di-O-tert-butyldimethylsilyl)cyclomaltoheptaose, heptakis(2-O-methyl-3,6-di-O-tert-butyldimethylsilyl)cyclomaltohep taose and heptakis(2-O-methyl)cyclomaltoheptaose intermediates. The structural identity of each intermediate and the final product was conclusively established by high-resolution MALDI-TOF mass spectrometry, variable-temperature 1H and 13C NMR spectroscopy and X-ray crystallography. The purity of each intermediate and the final product was determined by gradient high-performance liquid chromatography (HPLC) and indirect UV detection capillary electrophoresis.

Liquid chromatography-electrospray mass spectrometry as a tool for the analysis of sulfated oligosaccharides from mucin glycoproteins

An approach for analyzing sulfated oligosaccharide alditol mixtures by liquid chromatography-electrospray mass spectrometry (LC-ESI-MS) is described. Two columns, an amino-bonded column and a porous graphitized carbon column (PGC) were used. Oligosaccharides were eluted with linear gradients of acetonitrile and water, with 5 mM ammonium hydrogencarbonate or formate buffers at a basic pH. The methods were evaluated on a mixture of sulfated oligosaccharide alditols prepared from mucin glycoproteins from pig stomach. Results from LC-ESI-MS of the mixture were compared with the structural information obtained by high energy collision fragmentation using fast atom bombardment tandem mass spectrometry (FAB-MS-MS). The separation ability of the two columns was also tested using a more complex mixture of sulfated oligosaccharides from pig colon, where several isomers were detected. The potential use of in-source collision-induced dissociation (CID) to gain sequence information of sulfated oligosaccharides was also evaluated. The major fragment ions obtained by in-source CID of the trisaccharide Hex-3HexNAcol6-HexNAc6-SO3 were sufficient for assigning the oligosaccharide sequence and the position of the sulfate group within the monosaccharide moiety. The LC-ESI-MS approach should be a valuable tool for characterization of mucin glycosylation and alterations during pathological conditions.

Isolation and characterization of beta-cyclodextrin sulfates by preparative gradient polyacrylamide gel electrophoresis, capillary electrophoresis and electrospray ionization - mass spectrometry

A beta-cyclodextrin sulfate mixture has been fractionated using discontinuous gradient polyacrylamide gel electrophoresis. Semidry electrotransfer of the sample onto a positively charged nylon membrane and visualization of a portion of this membrane with Alcian blue stain showed multiple bands. The bands were cut from the remaining portion of the membrane and after washing with 8 M urea, the beta-cyclodextrin sulfate fractions were eluted with 2 M sodium chloride and dialyzed. Analysis of each fraction using high resolution analytical gradient polyacrylamide gel electrophoresis as well as capillary electrophoresis, using indirect detection, showed some of the fractions to be pure while others were mixtures. Each beta-cyclodextrin sulfate fraction was complexed with a basic synthetic peptide and analyzed by electrospray ionization mass spectrometry to define the mass of the components in each mixture and thereby to determine the purity of each sample.

Determination of the structure of oligosaccharides prepared from acharan sulfate

The fine structure of acharan sulfate, a recently discovered glycosaminoglycan isolated from Achatina fulica , was examined. This glycosaminoglycan has a major disaccharide repeating unit of -->4)-alpha-D-GlcNpAc(1-->4)-alpha-L-IdoAp2S(1--> (where GlcNpAc is N -acetylglucosamine, IdoAp is iduronic acid, and S is sulfate) making it structurally related to both heparin and heparan sulfate. Using heparin lyases prepared from Flavobacterium heparinum and a newly isolated heparinase from Bacteroides stercoris , the controlled enzymatic depolymerization of acharan sulfate was undertaken to prepare a mixture of oligosaccharides. Fractionation of this mixture of oligosaccharides by strong-anion-exchange high performance liquid chromatography afforded oligosaccharides that capillary electrophoresis established were sufficiently pure for structural characterization. Electrospray ionization mass spectrometry identified two series of oligosaccharides, one derived from acharan sulfate's major repeating unit and a second minor group of undersulfated oligosaccharides. Proton nuclear magnetic resonance spectroscopy established the structure of these two classes of oligosaccharides to be DeltaUAp2S(1-->[4)-alpha-D-GlcNpAc(1-->4)-alpha-L-IdoAp2S (1-->]n4)- D-GlcNpAcalpha,beta (where n = 0,1,2,3 and DeltaUAp is 4-deoxy-alpha-L- threo -hex-4-enopyranosyluronic acid) and DeltaUAp(1-->[4)- alpha-D-GlcNpAc(1-->4)-alpha-L-IdoAp2S(1-->]m-D-GlcNpAcal pha,beta (where m = 1,2,3). These results suggest the presence of minor sequence variants in acharan sulfate containing unsulfated iduronic acid having the structure -->4)-alpha-D-GlcNpAc(1-->4)-alpha-L-IdoAp(1-->.