Large-scale assignment of N-glycosylation sites using complementary enzymatic deglycosylation

Endoglycosidase is a class of glycosidases that specifically cleaves the glycosidic bond between two proximal residues of GlcNAc in the pentasaccharide core of N-glycan, leaving the innermost GlcNAc still attached to its parent protein, which provides a different diagnostic maker for N-glycosylation site assignment. This study aims to validate the use of endoglycosidase for high throughput N-glycosylation analysis. An endoglycosidase of Endo H and the conventional PNGase F were employed, with a similar accessible procedure, for large-scale assignment of N-glycosylation sites and then N-glycoproteome for rat liver tissue. ConA affinity chromatography was used to enrich selectively high-mannose and hybrid glycopeptides before enzymatic deglycosylation. As a result, a total of 1063 unique N-glycosites were identified by nano liquid chromatography tandem mass spectrometry, of which 53.0% were unknown in the Swiss-Prot database and 47.1% could be assigned only by either of the methods, confirmed the possibility of large-scale glycoproteomics by use of endoglycosidase. In addition, 11 glycosites were assigned with core-fucosylation by Endo H. A comparison between the two enzymatic deglycosylation methods was also investigated. Briefly, Endo H provides a more confident assignment but a smaller dataset compared with PNGase F, showing the complementary nature of the two N-glycosite assignment methods.     

Two-dimensional lectin affinity electrophoresis of alpha-fetoprotein: characterization of erythroagglutinating phytohemagglutinin-dependent microheterogeneity forms

By means of two-dimensional lectin affinity electrophoresis of human alpha-fetoprotein (AFP) from different sources, AFP bands separated with erythroagglutinating phytohemagglutinin (E-PHA) were further characterized with other lectins of known oligosaccharide specificities. The results with a cord serum AFP revealed that not only AFP-P2 (E-PHA-nonreactive) but also AFP-P4 and P5 (E-PHA-reactive) had affinities for Concanavalin A (Con A) and Allomyrina dichotoma lectin (allo A), indicating that the cord serum AFP has nonbisected biantennary complex-type oligosaccharides with the terminal galactose on Man alpha 1----6 residue sialylated at the C-6, but not C-3, position. On the other hand, the results with a hepatoblastoma (HUH-6 C1-5 cell line) AFP showed that not only AFP-P5 but also AFP-P1 (E-PHA-nonreactive) and P3 (E-PHA-less reactive) had Con A-nonreactive AFP and that AFP-P1 had AFP-A1 (allo A-nonreactive) and AFP-A2 (allo A-less reactive), and AFP-P3 and P4 had AFP-A1s (allo A-nonreactive), as main components, in addition to the spots of cord serum AFP. Most of the E-PHA-dependent bands of AFP were further subdivided with Lens culinaris agglutinin (LCA-A) into LCA-A-reactive, weakly reactive and nonreactive spots. Similar results were obtained with AFP preparations from hepatocellular carcinomas and other malignancies, indicating that the bisected bi-(or tri- and tetra-) antennary sugar chains with the exposed terminal galactose of the Man alpha 1----6 arm as well as those with the C-3 sialylated galactose residues could be expressed in AFP upon malignant transformation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Copper-glucosamine microcubes: synthesis, characterization, and C-reactive protein detection

Cubelike microstructures of glucosamine-functionalized copper (GlcN-CuMC's) have been fabricated by the integration of injection pump and ultrasonochemistry. Although bulk microstructures and the nanostructure of metallic copper exhibit distinct applications, the amino sugar surface-functionalized copper is almost biocompatible and exhibits advanced features such as more crystallinity, high thermal stability, and electrochemical feasibility toward biomolecule (C-reactive protein, CRP) detection. An electrochemical test of this GlcN-CuMC's was demonstrated by immobilization on a conventional gold-PCB (Au-PCB) electrode. The combination of a biointerface membrane, from glucosamine functionalization, and electroactive sites of metallic copper provides a very efficient electrochemical response against various concentration of CRP. A perfect scaling of steady-state currents with r(2) values of 0.9862 (I(pa)) and 0.9972 (I(pc)) indicate the promise of this kind of biofunctionalized microstructure electrode for many surface and interface applications.     

Determination of N-glycosylation sites and site heterogeneity in a monoclonal antibody by electrospray quadrupole ion-mobility time-of-flight mass spectrometry

This paper presents an improved analytical method for glycosylation structural characterizations of a monoclonal antibody (mAb) using a newly developed quadrupole ion-mobility time-of-flight (ESI-Q-IM-TOF) mass spectrometer. Using this method, high-resolution mass spectra were acquired to produce the overall glycosylation profile of the mAb. Additionally, the light and heavy chains from the reduced antibody were separated in the gas phase by the ion mobility functionality of the instrument, allowing accurate mass measurement of each subunit. Furthermore, the glycan sequences, as well as the glycosylation site, were determined by a two-step sequential fragmentation process using the unique dual-collision-cell design of the instrument, thus providing detailed characterizations of the glycan structures.     

甲胺化衍生结合基于硅氢化物固定相的正相色谱用于单克隆抗体药物的N-糖基化表征

采用甲胺化衍生结合基于硅氢化物固定相的正相色谱（SiH-NPC）分析单抗的N-糖基化。样品经酶切、甲胺化衍生、纯化后由液相色谱-质谱进行分析。结果表明,相较于亲水相互作用色谱（HILIC）,SiH-NPC分离机制不同,使用常规的无盐流动相即可实现高分离度,避免污染质谱,色谱柱结构稳定,使用寿命长,更适合快速分析。结合唾液酸衍生方法,SiH-NPC在液相色谱-质谱联用鉴定酸性糖和糖异构体方面呈现显著优势,在生物制药行业中具有重要的应用潜力。     

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.     

Mass spectrometric characterization of glycosylation of hepatitis C virus E2 envelope glycoprotein reveals extended microheterogeneity of N-glycans

Hepatitis C virus (HCV) causes acute and chronic liver disease in humans, including chronic hepatitis, cirrhosis, and hepatocellular carcinoma. The polyprotein encoded in the HCV genome is co- and post-translationally processed by host and viral peptidases, generating the structural proteins Core, E1, E2, and p7, and five nonstructural proteins. The two envelope proteins E1 and E2 are heavily glycosylated. Studying the glycan moieties attached to the envelope E2 glycoprotein is important because the N-linked glycans on E2 envelope protein are involved in the interaction with some human neutralizing antibodies, and may also have a direct or indirect effect on protein folding. In the present study, we report the mass spectrometric characterization of the glycan moieties attached to the E2 glycoprotein. The mass spectrometric analysis clearly identified the nature, composition, and microheterogeneity of the sugars attached to the E2 glycopeptides. All 11 sites of glycosylation on E2 protein were characterized, and the majority of these sites proved to be occupied by high mannose glycans. However, complex type oligosaccharides, which have not been previously identified, were exclusively observed at two N-linked sites, and their identity and heterogeneity were determined.     

Classification of water molecules in protein binding sites

Water molecules play a crucial role in mediating the interaction between a ligand and a macromolecular receptor. An understanding of the nature and role of each water molecule in the active site of a protein could greatly increase the efficiency of rational drug design approaches: if the propensity of a water molecule for displacement can be determined, then synthetic effort may be most profitably applied to the design of specific ligands with the displacement of this water molecule in mind. In this paper, a thermodynamic analysis of water molecules in the binding sites of six proteins, each complexed with a number of inhibitors, is presented. Two classes of water molecules were identified: those conserved and not displaced by any of the ligands, and those that are displaced by some ligands. The absolute binding free energies of 54 water molecules were calculated using the double decoupling method, with replica exchange thermodynamic integration in Monte Carlo simulations. It was found that conserved water molecules are on average more tightly bound than displaced water molecules. In addition, Bayesian statistics is used to calculate the probability that a particular water molecule may be displaced by an appropriately designed ligand, given the calculated binding free energy of the water molecule. This approach therefore allows the numerical assessment of whether or not a given water molecule should be targeted for displacement as part of a rational drug design strategy.     

Improved mapping of protein binding sites

Computational mapping methods place molecular probes – small molecules or functional groups – on a protein surface in order to identify the most favorable binding positions by calculating an interaction potential. Mapping is an important step in a number of flexible docking and drug design algorithms. We have developed improved algorithms for mapping protein surfaces using small organic molecules as molecular probes. The calculations reproduce the binding of eight organic solvents to lysozyme as observed by NMR, as well as the binding of four solvents to thermolysin, in good agreement with x-ray data. Application to protein tyrosine phosphatase 1B shows that the information provided by the mapping can be very useful for drug design. We also studied why the organic solvents bind in the active site of proteins, in spite of the availability of alternative pockets that can very tightly accommodate some of the probes. A possible explanation is that the binding in the relatively large active site retains a number of rotational states, and hence leads to smaller entropy loss than the binding elsewhere else. Indeed, the mapping reveals that the clusters of the ligand molecules in the protein's active site contain different rotational-translational conformers, which represent different local minima of the free energy surface. In order to study the transitions between different conformers, reaction path and molecular dynamics calculations were performed. Results show that most of the rotational states are separated by low free energy barriers at the experimental temperature, and hence the entropy of binding in the active site is expected to be high.     

Comprehensive characterization of the N-glycosylation status of CD44s by use of multiple mass spectrometry-based techniques

The CD44 family are type-1 transmembrane glycoproteins which are important in mediating the response of cells to their microenvironment, including regulation of growth, survival, differentiation, and motility. All these important functions have been reported to be regulated by N-glycosylation; however, little is known about this process. In the CD44 family, the most prolific isoform is CD44 standard type (CD44s). In this work, an integrated strategy combining stable isotope labeling, chemical derivatization, hydrophilic-interaction liquid chromatographic (HILIC) separation, and mass spectrometric (MS) identification was used to perform a comprehensive qualitative and quantitative survey of the N-glycosylation of recombinant CD44s. Specifically, the occupation ratios of the N-glycosites were first determined by MS with (18)O labeling; the results revealed five glycosites with different occupation ratios. Next, N-glycans were profiled by chemical derivatization and exoglycosidase digestion, followed by MALDI-TOF-MS and HILIC-ESI-MS-MS analysis. Interestingly, the quantitative analysis showed that non-sialylated, fucosylated complex-type glycans dominated the N-glycans of CD44s. Furthermore, the site-specific N-glycan distributions profiled by LC-ESI-MS(E) indicated that most glycosites bore complex-type glycans, except for glycosite N100, which was occupied by high-mannose-type N-glycans. This is the first comprehensive report of the N-glycosylation of CD44s. Figure Strategies for characterization of the N-glycosylation status of CD44s.     

Improving detection limits in chromatography by signal averaging

Ensemble or signal averaging has been used to increase detection limits in gas chromatography. The sample is injected several times into a gas chromatograph and the chromatograms generated are summed. The resulting chromatogram is treated as a separate chromatogram with the benefit of an improved signal-to-noise ratio. Use of the technique enables reliable quantitation, the time invested being used to convert an unacceptable signal-to-noise ratio into useful data. A discussion and some applications of the technique are described.     

Improving protein identification from peptide mass fingerprinting through a parameterized multi-level scoring algorithm and an optimized peak detection

We have developed a new algorithm to identify proteins by means of peptide mass fingerprinting. Starting from the matrix-assisted laser desorption/ionization-time-of-flight (MALDI-TOF) spectra and environmental data such as species, isoelectric point and molecular weight, as well as chemical modifications or number of missed cleavages of a protein, the program performs a fully automated identification of the protein. The first step is a peak detection algorithm, which allows precise and fast determination of peptide masses, even if the peaks are of low intensity or they overlap. In the second step the masses and environmental data are used by the identification algorithm to search in protein sequence databases (SWISS-PROT and/or TrEMBL) for protein entries that match the input data. Consequently, a list of candidate proteins is selected from the database, and a score calculation provides a ranking according to the quality of the match. To define the most discriminating scoring calculation we analyzed the respective role of each parameter in two directions. The first one is based on filtering and exploratory effects, while the second direction focuses on the levels where the parameters intervene in the identification process. Thus, according to our analysis, all input parameters contribute to the score, however with different weights. Since it is difficult to estimate the weights in advance, they have been computed with a generic algorithm, using a training set of 91 protein spectra with their environmental data. We tested the resulting scoring calculation on a test set of ten proteins and compared the identification results with those of other peptide mass fingerprinting programs.     

Discrimination between peak spreading in capillary zone electrophoresis of proteins due to interaction with the capillary wall and due to protein microheterogeneity

Our study attempts to find an approach to distinguishing between the contribution to peak spreading in capillary zone electrophoresis (CZE) due to protein microheterogeneity and that due to interaction with the capillary wall, by analyzing correlations between observed peak spreading and peak asymmetry. The peak asymmetry was measured as ln[(tm-t1)/(t2-tm)] where tm, t1, and t2 are migration times at the mode of the peak and at the intersection of the peak width at half-height with the ascending and descending limbs, respectively. Two isoforms of recombinant green fluorescent protein (GFP-1 and GFP-2, 27 kDa molecular mass), glucose-6-phosphate dehydrogenase (GPD, 104 kDa), and the naturally fluorescent protein R-phycoerythrin (PHYCO, 240 kDa) were subjected to CZE in polyacrylamide-coated fused-silica capillaries of 50 and 100 microns diameters under varying conditions of protein concentration, field strength, and the initial zone length. Under conditions such that contributions to peak spreading from axial diffusion, thermal effects, and electrophoretic dispersion are negligible, the analysis of the interrelations between peak width and peak asymmetry was found to allow a conclusion as to the cause of peak spreading in CZE of protein. It appears that the peak width of GFP-2 originates mostly in protein microheterogeneity while that of GFP-1 is due to protein-capillary wall interactions. For PHYCO, both microheterogeneity and protein-capillary wall interactions contribute to peak spreading. GPD exhibits relatively little microheterogeneity or interaction with capillary walls. Thus, its peak width appears to be mostly affected by an extracolumn source of spreading such as the initial zone length.     

Identifying reaction intermediates and catalytic active sites through in situ characterization techniques

This tutorial review centers on recent advances and applications of experimental techniques that help characterize surface species and catalyst structures under in situ conditions. We start by reviewing recent applications of IR spectroscopy of working catalysis, emphasizing newer approaches such as Sum Frequency Generation and Polarization Modulation-infrared reflection absorption spectroscopy. This is followed by a section on solid-state NMR spectroscopy for the detection of surface species and reaction intermediates. These two techniques provide information mainly about the concentration and identity of the prevalent surface species. The following sections center on methods that provide structural and chemical information about the catalyst surface. The increasingly important role of high-pressure X-ray photoelectron spectroscopy in catalyst characterization is evident from the new and interesting information obtained on supported catalysts as presented in recent reports. X-Ray absorption spectroscopy (XANES and EXAFS) is used increasingly under reaction conditions to great advantage, although is inherently limited to systems where the bulk of the species in the sample are surface species. However, the ability of X-rays to penetrate the sample has been used cleverly by a number of groups to understand how changing reaction conditions change the structure and composition of surface atoms on supported catalyst.     

Accreditation of GMO detection laboratories: Improving the reliability of GMO detection

Reliable and efficient methods for detecting genetically modified organisms (GMOs) are essential for establishing an effective system for traceability all along the supply chain from seed producers to final consumers. The latter is especially meaningful in European Union and other countries where strict legislations on GMOs were set up. Performance of the methods used in laboratories around the world should be uniform, in order to obtain reliable and comparable results. Accreditation is a suitable system for harmonising procedures in each testing laboratory. In this paper, key elements for the accreditation of molecular biology methods for GMO detection according to ISO/IEC 17025 are described. The procedures described are also valuable for the accreditation of molecular methods for all laboratory diagnostics where qualitative and quantitative characterisation of nucleic acids is needed.     

Improved tandem mass spectrometric characterization of 3-nitrotyrosine sites in peptides

Nitrated tyrosines are easily converted into their aminotyrosine equivalents by a reduction step. We here show that this conversion can be exploited to readily discern 3-aminotyrosine peptides in a background of non-nitrated peptides. Furthermore, aminotyrosine peptides are more stable in single mass spectrometry (MS) mode rendering peptide mass maps easier to interpret. One significant caveat of both 3-nitrotyrosine and 3-aminotyrosine peptides is their lack of efficient fragmentation upon collision-induced dissociation (CID) which, in the case of the latter peptides, also produces unexpected, deviating isotopic patterns of fragment ions containing the aminotyrosine residue. The net result is that sequence database searching becomes daunting as the correct peptide is frequently missed since insufficient and/or inaccurate peptide fragments are used. We show that a simple acetylation step, blocking all amines (including aminotyrosine), produces peptides that undergo extensive backbone fragmentation by CID and are thus easily identifiable in databases. Our procedure is additionally illustrated by doubling the number of nitration events mapped in tetranitromethane-nitrated bovine serum albumin (BSA) as compared to a direct analysis of the nitrated peptides using the same amount of material. In conclusion, we here illustrate that this two-step process, heme-mediated reduction and acetylation, can be used for more efficient characterization of protein-bound nitrated tyrosines.