Discrimination of cellular developmental states focusing on glycan transformation and membrane dynamics by using BODIPY-tagged lactosyl ceramides.

Glycosphingolipids (GSLs) are a group of molecules composed of a hydrophilic glycan part and a hydrophobic ceramide creating a diverse family. GSLs are de novo synthesised from ceramides at the endoplasmic reticulum and Golgi apparatus, and transported to the outer surface of the plasma membrane. It has been known that the glycan structures of GSLs change reflecting disease states. We envisioned that analysing the glycan pattern of GSLs enables distinguishing diseases. For this purpose, we utilised a fluorescently tagged compound, LacCerBODIPY (1). At first, compound 1 was taken up by cultured PC12D cells and transformed into various GSLs. As a result, changes in the GSL patterns of differentiation states of the cells were successfully observed by using an analysis platform, nano-liquid chromatography (LC)-fluorescence detection (FLD)-electrospray ionisation (ESI)-mass spectrometry (MS), which could quantify and provide molecular ions simultaneously. We found that compound 1 remained for about 10 min on the plasma membrane before it was converted into other GSLs. We therefore investigated a more rapid way to discriminate different cellular states by fluorescence recovery after photobleaching, which revealed that it is possible to distinguish the differentiation states as well.

Analysis of the cellular dynamics of fluorescently tagged glycosphingolipids by using a nanoliquid chromatography-tandem mass spectrometry platform.

Despite the increasing biological interests on glycoconjugates, the synthetic mechanism of oligosaccharides has not yet been revealed except for the enzymes involved. To clarify the synthetic events that occur inside cells, spatiotemporal analysis of fluorescently tagged glycosphingolipids was carried out. Transformation of the incorporated lactosylceramide analogue carrying 4,4-difluoro-5,7-dimethyl-4-bora-3a,4a-diaza-s-indacene-3-propionyl group (BODIPY fluorophore) was analyzed using nanoLC-fluorescence detection-nanoelectrospray ionization-mass spectrometry. A complex process of glycan synthesis and degradation was our primary observation.

Fluorescence-monitored zero dead-volume nanoLC-microESI-QIT-TOF MS for analysis of fluorescently tagged glycosphingolipids.

An analysis of the glycan processing event is of particular importance to understand the nontemplate dependent synthetic mechanism of the multiple glycosylation reactions taking place in the Golgi apparatus in connection with the post-translational modification of biomolecules. In our efforts to address the issue, we constructed an analysis platform using nano-liquid chromatography (LC), which also worked as a spray tip, with an optical-fiber-based blue (470 nm) light emitting diode (LED)-induced fluorescence (520 nm) detector coupled with a microelectrospray ionization (ESI)-quadrupole ion trap (QIT)-time of flight (TOF) mass spectrometer (MS). This system was designed to enable both quantitative and qualitative analyses of fluorescently tagged molecules such as BODIPY-tagged lactosylceramide. Owing to the zero dead volume after LC separation, an extremely high sensitivity was achieved for the quantitative analysis (260 amol). It was also shown that a simultaneous online structural analysis based on MS could be achieved for the same quantity of analyte. To further demonstrate its potential, an enzymatic reaction of fluorescently tagged lactosylceramide using sialyltransferase was carried out, and the conversion yield was obtained on the basis of fluorescence detection. In addition, the structural details of a product, sialyl lactosylceramide, were obtained by MS and MS/MS analyses.

Energy-resolved structural details obtained from gangliosides.

Gangliosides, a family of glycosphingolipids (GSLs) that comprise sialic acid residue(s), are an important class of molecules that exist on the outer surface of the plasma membrane. To assess the functions of a particular series of gangliosides that play important roles in brain functions, their structures and localizations need to be investigated. We studied the structures of these gangliosides by collision-induced dissociation using quadrupole ion-trap mass spectrometry. The dissociation processes were investigated in detail based on energy-resolved mass spectrometry using sodiated molecules. The decision of utilization of the positive mode was based on the assumption that it was the generally applicable method for GSLs, including neutral ones. In this investigation, sialic acid residues were esterified to stabilize the linkages and to generate multiple fragment ions for successful structural investigations. A detailed analysis of a series of sodiated species of gangliosides based on energy-resolved mass spectrometry revealed that the GM1-equivelent fragments generated from the precursor ions under low energy CID conditions had the structural characteristics of their individual precursors. It was suggested that this information will be useful in determining the structures of their precursor gangliosides.

Analysis of behavior of sodiated sugar hemiacetals under low-energy collision-induced dissociation conditions and application to investigating mutarotation and mechanism of a glycosidase.

Analysis of anomericity is one of the most important issues in the structure elucidation of carbohydrates. Mass spectrometry (MS)-based methods are of particular interest and important to address the issue related to resolving anomericity of monosaccharide units in a glycan. However, direct analysis of hemiacetals has not been possible by MS because of the nonavailability of information regarding the gas-phase behavior of such ion species. We addressed this issue by using stage-discriminated energy-resolved mass spectrometry (ERMS) at the stages of MS(n) and MS(n+1) and showed that such analysis can be made. This was achieved by proving that individual anomers can be identified and that the equilibrium of sodium adducted ion species of alpha- and beta-anomers can be negated in the gas phase under collision-induced dissociation (CID) conditions. On the basis of these results, we could 1) observe the mutarotation of lactose and 2) speculate the hydrolysis mechanism of endo-glycosylceramidase by using mass spectrometry.

Reactivation of hyperglycemia-induced hypocretin (HCRT) gene silencing by N-acetyl-d-mannosamine in the orexin neurons derived from human iPS cells.

Orexin neurons regulate critical brain activities for controlling sleep, eating, emotions, and metabolism, and impaired orexin neuron function results in several neurologic disorders. Therefore, restoring normal orexin function and understanding the mechanisms of loss or impairment of orexin neurons represent important goals. As a step toward that end, we generated human orexin neurons from induced pluripotent stem cells (hiPSCs) by treatment with N-acetyl-d-mannosamine (ManNAc) and its derivatives. The generation of orexin neurons was associated with DNA hypomethylation, histone H3/H4 hyperacetylation, and hypo-O-GlcNAcylation on the HCRT gene locus, and, thereby, the treatment of inhibitors of SIRT1 and OGT were effective at inducing orexin neurons from hiPSCs. The prolonged exposure of orexin neurons to high glucose in culture caused irreversible silencing of the HCRT gene, which was characterized by H3/H4 hypoacetylation and hyper-O-GlcNAcylation. The DNA hypomethylation status, once established in orexin neurogenesis, was maintained in the HCRT-silenced orexin neurons, indicating that histone modifications, but not DNA methylation, were responsible for the HCRT silencing. Thus, the epigenetic status of the HCRT gene is unique to the hyperglycemia-induced silencing. Intriguingly, treatment of ManNAc and its derivatives reactivated HCRT gene expression, while inhibitors SIRT1 and the OGT did not. The present study revealed that the HCRT gene was silenced by the hyperglycemia condition, and ManNAc and its derivatives were useful for restoring the orexin neurons.

Syntheses of lactosyl ceramide analogues carrying novel bifunctional BODIPY dyes directed towards the differential analysis of multiplexed glycosphingolipids by MS/MS using iTRAQ.

Lactosyl ceramide analogues carrying novel bifunctional BODIPY-based fluorescent tags were designed and synthesised for live cell imaging. Addition of azide functionality on the fluorophore facilitated isobaric tagging for quantitative multiplexed analysis of biomolecules based on tandem mass spectrometry.

Synthesis of a fluorescently tagged sialic acid analogue useful for live-cell imaging.

A cytidine 5'-monophosphate (CMP)-sialic acid analogue carrying a fluorescent reporter group, an inhibitor of sialyltransferase, was synthesised in order to investigate glycan synthesis events in cells. The compound was found to be a substrate of a CMP-sialic acid transporter, and specific Golgi vesicles were visualised in the cells.

Ion-trap mass spectrometry unveils the presence of isomeric oligosaccharides in an analyte: stage-discriminated correlation of energy-resolved mass spectrometry.

Mass spectrometry, especially tandem mass spectrometry, has been widely used in the field of analytical sciences for handling biological and chemical samples. The technique resolves molecular and fragment ions based on the mass to charge ratio. Energy-resolved mass spectrometry (ERMS) further provides an activation energy-related factor in the dissociation reaction. Therefore, it is a very powerful technique that can discriminate isomeric compounds. Despite the power of ERMS, useful information cannot be obtained when an analyte contains structural isomers. Carbohydrates carry multiple chiral centers, thus oligomers of monosaccharides can form a vast number of structural isomers. We decided to use such species in our endeavors to establish a method of identifying the 'purity' of an analyte solely based on mass spectrometry. In the present paper, we describe a stage-discriminated spectral correlation of ERMS, which not only enables identification of the presence of contaminants in an analyte, but also provides information regarding the 'purity' of fragment ions.

High-yielding and controlled dissociation of glycosides producing B- and C-ion species under collision-induced dissociation MS/MS conditions and use in structural determination.

Collision-induced dissociation (CID) in mass spectrometry is a powerful technique with which to understand gas-phase chemical reactions. A mass spectrometer is used to carry out the reaction, isolation, and analysis. On the other hand, structural analysis of glycan structures is of extreme importance in the analysis of biomolecules, such as glycoproteins and glycolipids. In the analysis of glycan structures based on CID, certain ion species, including B-/Y-, C-/Z-, and A-/X-ions, are produced. Among these ions, we are interested in C-ion species that carry a glycosyl oxygen atom at the anomeric center and that possibly provide information regarding anomeric configuration. A method for generating C-ion species when necessary is thus considered to be important; however, none is currently available. In this study, synthetic glycosides carrying a series of aglycons were analyzed with the aim of identifying suitable glycosides with which to produce C-ions to be used in the structural determination of oligosaccharides. The results showed a 4-aminobutyl group was an excellent candidate. Furthermore, the use of C-ion species obtained in this manner in the structural characterization of a ganglioside, GM3, is described. The type of glycoside is believed to be valuable not only in structural analysis but also in biological investigation, because of the existing amino functionality that has been proven to be useful by enabling the generation of conjugates with other molecules and materials.