Use of a stable-isotope-labeled reporter peptide and antioxidants for reliable quantification of methionine oxidation in a monoclonal antibody by liquid chromatography/mass spectrometry.

RATIONALE: Accurate quantification of methionine oxidation in therapeutic proteins by liquid chromatography/mass spectrometry (LC/MS) is challenging due to the potential artifacts introduced during sample preparation and analysis in the peptide mapping workflow. In this study, a systematic approach for optimization of the peptide mapping procedure to achieve reliable quantification of endogenous methionine oxidation in monoclonal antibodies was developed. METHODS: The approach is based on usage of a stable-isotope-labeled reporter peptide, identical in sequence to the tryptic peptide of an IgG1 monoclonal antibody containing the methionine residue most prone to oxidation. This approach was applied to evaluating various desalting procedures, and tested on nanoLC/MS, microLC/MS and UPLC/MS for the peptide mapping analysis of a model monoclonal antibody IgG1 sensitive to oxidation. RESULTS: Several steps in the peptide mapping procedure with LC/MS detection at which protein oxidation occurred were identified and optimized using the reference stable-isotope-labeled peptide. Thus, reliable quantification of methionine oxidation in the target monoclonal antibody was validated. CONCLUSIONS: The methodology which utilizes the reference stable-isotope-labeled reporter peptide is applicable to monoclonal antibody oxidation analysis and could be extended to other biotherapeutics once oxidation-prone methionine(s) in the protein sequence are identified. Copyright © 2016 John Wiley & Sons, Ltd.

Electrical percolation thresholds of semiconducting single-walled carbon nanotube networks in field-effect transistors.

With the advances in the separation and purification of carbon nanotubes (CNTs), the use of highly pure metallic or semiconducting CNTs has practical merit in electronics applications. When highly pure CNTs are applied in various fields, CNT networks are preferred to individual CNTs. In such cases, the presence of an electrical path becomes crucial in the network. In this study, we report on the electrical percolation thresholds of semiconducting single-walled carbon nanotube (s-SWCNT) networks, and their electrical characteristics in field-effect transistors (FET). Using the Monte Carlo method, s-SWCNT networks were randomly generated in the channels defined by the source-drain electrodes of the FET. On the basis of percolation theory, the percolation thresholds of s-SWCNT networks were obtained at different channel lengths (2, 6, and 10 µm) by generating random s-SWCNT networks 100 times. The network density corresponding to the electrical percolation threshold was theoretically gained at each channel length. As a result, the network densities at the percolation thresholds for the channel lengths of 2, 6, and 10 µm were 6.8, 9.0, and 9.9 tube µm(-2), respectively. In addition, SPICE calculations were performed for each s-SWCNT network, constituting an electrical path between the source and the drain electrodes of the FET. In all channel lengths, the on/off ratio of the s-SWCNT networks was enhanced with increasing network density. Finally, we found a power law relationship between the on/off ratio of the s-SWCNT networks and the network density at the percolation threshold.

Chemical and cytokine features of innate immunity characterize serum and tissue profiles in inflammatory bowel disease.

Inflammatory bowel disease (IBD) arises from inappropriate activation of the mucosal immune system resulting in a state of chronic inflammation with causal links to colon cancer. Helicobacter hepaticus-infected Rag2(-/-) mice emulate many aspects of human IBD, and our recent work using this experimental model highlights the importance of neutrophils in the pathology of colitis. To define molecular mechanisms linking colitis to the identity of disease biomarkers, we performed a translational comparison of protein expression and protein damage products in tissues of mice and human IBD patients. Analysis in inflamed mouse colons identified the neutrophil- and macrophage-derived damage products 3-chlorotyrosine (Cl-Tyr) and 3-nitrotyrosine, both of which increased with disease duration. Analysis also revealed higher Cl-Tyr levels in colon relative to serum in patients with ulcerative colitis and Crohn disease. The DNA chlorination damage product, 5-chloro-2'-deoxycytidine, was quantified in diseased human colon samples and found to be present at levels similar to those in inflamed mouse colons. Multivariate analysis of these markers, together with serum proteins and cytokines, revealed a general signature of activated innate immunity in human IBD. Signatures in ulcerative colitis sera were strongly suggestive of neutrophil activity, and those in Crohn disease and mouse sera were suggestive of both macrophage and neutrophil activity. These data point to innate immunity as a major determinant of serum and tissue profiles and provide insight into IBD disease processes.

A dual analyzer for real-time impedance and noise spectroscopy of nanoscale devices.

This paper introduces a simple portable dual analyzer which allows real-time ac-impedance measurements and noise spectroscopic analysis simultaneously, employing one or two data acquisition systems together with a low noise current-to-voltage preamplifier. The input signal composed of numerous selected frequencies of sinusoidal voltages with a dc bias was applied to a device under the test (DUT): single walled carbon nanotube field effect transistors (SWCNT-FETs). Each frequency component, ranging from 1 to 46.4 kHz, was successfully mapped to a Nyquist plot using the background of the electrical noise power spectrum. It is, thus, clearly demonstrated that this dual analyzer enables the real-time ac-impedance analysis and the frequency response of the carrier transport in the SWCNT-FETs as a DUT.

Glycomic Alterations in the Highly-abundant and Lesser-abundant Blood Serum Protein Fractions for Patients Diagnosed with Hepatocellular Carcinoma.

Hepatocellular cancer is a serious human disease with an unfortunately low survival rate. It further poses a significant epidemic threat to our society through its viral vectors associated with cirrhosis conditions preceding the cancer. A search for biomarkers of these diseases enlists analytical glycobiology, in general, and quantitative biomolecular mass spectrometry (MS), in particular, as valuable approaches to cancer research. The recent advances in quantitative glycan permethylation prior to MALDI-MS oligosaccharide profiling has enabled us to compare the glycan quantitative proportions in the small serum samples of cancer and cirrhotic patients against control individuals. We were further able to fractionate the major serum proteins from the minor components and compare statistically their differential glycosylation, elucidating some causes of quantitatively unusual glycosylation events. Numerous glycan structures were tentatively identified and connected with the origin proteins, with a particular emphasis on sialylated and fucosylated glycans.

Analysis of site-specific glycosylation of renal and hepatic γ-glutamyl transpeptidase from normal human tissue.

The cell surface glycoprotein γ-glutamyl transpeptidase (GGT) was isolated from healthy human kidney and liver to characterize its glycosylation in normal human tissue in vivo. GGT is expressed by a single cell type in the kidney. The spectrum of N-glycans released from kidney GGT constituted a subset of the N-glycans identified from renal membrane glycoproteins. Recent advances in mass spectrometry enabled us to identify the microheterogeneity and relative abundance of glycans on specific glycopeptides and revealed a broader spectrum of glycans than was observed among glycans enzymatically released from isolated GGT. A total of 36 glycan compositions, with 40 unique structures, were identified by site-specific glycan analysis. Up to 15 different glycans were observed at a single site, with site-specific variation in glycan composition. N-Glycans released from liver membrane glycoproteins included many glycans also identified in the kidney. However, analysis of hepatic GGT glycopeptides revealed 11 glycan compositions, with 12 unique structures, none of which were observed on kidney GGT. No variation in glycosylation was observed among multiple kidney and liver donors. Two glycosylation sites on renal GGT were modified exclusively by neutral glycans. In silico modeling of GGT predicts that these two glycans are located in clefts on the surface of the protein facing the cell membrane, and their synthesis may be subject to steric constraints. This is the first analysis at the level of individual glycopeptides of a human glycoprotein produced by two different tissues in vivo and provides novel insights into tissue-specific and site-specific glycosylation in normal human tissues.

Solid-phase permethylation for glycomic analysis.

This chapter discusses in detail a miniaturized version of the widely used permethylation technique which permits quantitative derivatization of oligosaccharides derived from minute quantities of glycoprotein. The approach involves packing of sodium hydroxide powder or beads in a microcolumn format, including spin columns, fused silica capillaries (500 microm i.d.) and plastic tubes (1 mm i.d.). The derivatization proceeds effectively in less than a minute time scale and it is applicable to glycans derived from femtomole quantities of glycoproteins. Prior to mass spectrometry (MS), methyl iodide is added to analytes suspended in dimethyl sulfoxide solution containing traces of water. The reaction mixture is then immediately infused through the microreactor. The packed sodium hydroxide powder or beads inside the microcolumns minimize oxidative degradation and peeling reactions which are otherwise commonly associated with the conventional permethylation technique. In addition, this solid-phase permethylation approach eliminates the need for excessive sample clean-up. As demonstrated below, picomole amounts of various types of glycans derived from model glycoproteins as well as real samples, including linear and branched, sialylated and neutral glycans were shown to become rapidly and efficiently permethylated through this approach.

Glycomic profiling of invasive and non-invasive breast cancer cells.

Quantitative profiling of glycans with different structures appears essential for a better understanding of the cellular adhesion phenomena associated with malignant transformation and the underlying aberrant glycosylation of cancer cells. Using the recently developed glycomic techniques and mass-spectrometric measurements, we compare the N-linked and O-linked oligosaccharide profiles for different breast cancer cell lines with those of normal epithelial cells. Statistically significant differences in certain neutral, sialylated and fucosylated structures are readily discerned through quantitative measurements, indicating a potential of distinguishing invasive and non-invasive cancer attributes. The glycomic profile data cluster accordingly using Principal Component Analysis, verifying further glycobiological differences due to the differences between normal and cancer cell lines.

Identification of isomeric N-glycan structures by mass spectrometry with 157 nm laser-induced photofragmentation.

Characterization of structural isomers has become increasingly important and extremely challenging in glycobiology. This communication demonstrates the capability of ion-trap mass spectrometry in conjunction with 157 nm photofragmentation to identify different structural isomers of permethylated N-glycans derived from ovalbumin without chromatographic separation. The results are compared with collision-induced dissociation (CID) experiments. Photodissociation generates extensive cross-ring fragment ions as well as diagnostic glycosidic product ions that are not usually observed in CID MS/MS experiments. The detection of these product ions aids in characterizing indigenous glycan isomers. The ion trap facilitates MS(n) experiments on the diagnostic glycosidic fragments and cross-ring product ions generated through photofragmentation, thus allowing unambiguous assignment of all of the isomeric structures associated with the model glycoprotein used in this study. Photofragmentation is demonstrated to be a powerful technique for the structural characterization of glycans.

Breast cancer diagnosis and prognosis through quantitative measurements of serum glycan profiles.

BACKGROUND: Glycosylated proteins play important roles in cell-to-cell interactions, immunosurveillance, and a variety of receptor-mediated and specific protein functions through a highly complex repertoire of glycan structures. Aberrant glycosylation has been implicated in cancer for many years. METHODS: We performed specific MALDI mass spectrometry (MS)-based glycomic profile analyses of permethylated glycans in sera from breast cancer patients (12, stage I; 11, stage II; 9, stage III; and 50, stage IV) along with sera from 27 disease-free women. The serum glycoproteins were enzymatically deglycosylated, and the released glycans were purified and quantitatively permethylated before their MALDI-MS analyses. We applied various statistical analysis tools, including ANOVA and principal component analysis, to evaluate the MS profiles. RESULTS: Two statistical procedures implicated several sialylated and fucosylated N-glycan structures as highly probable biomarkers. Quantitative changes according to a cancer stage resulted when we categorized the glycans according to molecular size, number of oligomer branches, and abundance of sugar residues. Increases in sialylation and fucosylation of glycan structures appeared to be indicative of cancer progression. Different statistical evaluations confirmed independently that changes in the relative intensities of 8 N-glycans are characteristic of breast cancer (P < 0.001), whereas other glycan structures might contribute additionally to distinctions in the statistically recognizable patterns (different stages). CONCLUSIONS: MS-based N-glycomic profiling of serum-derived constituents appears promising as a highly sensitive and informative approach for staging the progression of cancer.

High-throughput solid-phase permethylation of glycans prior to mass spectrometry.

Permethylation of glycans prior to their mass spectrometric determination has now become a time-honored methodology in glycoconjugate analysis due to the advantage of a simultaneous analysis of neutral and acidic glycans as well as enhanced sensitivity and easier tandem mass spectrometry interpretation. While the different solvent extraction-based versions of this method often suffice in different structural studies, they are generally less satisfactory in the quantitative determinations aiming at minor quantities of the analyzed materials. To overcome these difficulties, we recently introduced a solid-phase capillary permethylation technique (Kang et al., Rapid Commun. Mass Spectrom. 2005; 19: 3421) for microscale determination. Here, we describe a very useful high-throughput extension of the solid-phase methodology utilizing spin columns packed with sodium hydroxide beads. This procedure has been thoroughly optimized to match the analytical performance parameters of the previously used capillary technique. As demonstrated with a high-precision glycomic profiling analysis of human blood serum, this methodological improvement offers simplicity and reproducibility, allowing the complete permethylation of 12-18 samples in less than 20 min.

Comparative glycomic mapping through quantitative permethylation and stable-isotope labeling.

Comparative glycan quantification has thus far been a challenging task due to the lack of sensitive and reproducible analytical techniques. We introduce here a combination of quantitative permethylation and isotope labeling of glycans as an approach (C-GlycoMAP) allowing precise comparison between different samples in a single MALDI-MS analysis. Samples are either methylated or deuteriomethylated prior to their mixing and mass spectrometric acquisitions. Comparative analyses are based on the ratio of the two isotopically distinct forms of the same glycan structure, thus allowing a direct absolute evaluation of the intensities of the two forms originating from two different biological samples (e.g., control and diseased). The direct comparison between the two forms eliminates a MALDI-MS low m/z bias commonly associated with this technique. These comparative analyses are highly reliable when the intensity ratios of the two forms lie between 0.125 and 6, an overall reproducibility better than 30% (RSD). The value of C-GlycoMAP is demonstrated here for N-glycans derived from human blood serum collected from a healthy individual and a breast cancer patient as well as for O-glycans derived from normal and cancer cell extracts.

A novel function of VCP (valosin-containing protein; p97) in the control of N-glycosylation of proteins in the endoplasmic reticulum.

alpha-Chain of T-cell receptor (TCR) is a typical ERAD (ER-associated degradation) substrate degraded in the absence of other TCR subunits. Depletion of derlin 1 fails to induce accumulation of alphaTCR despite inducing accumulation of alpha1-antitrypsin, another ERAD substrate. Furthermore, while depletion of VCP does not affect levels of alpha1-antitrypsin, it induces an increase in levels of alphaTCR. RNAi of VCP induces preferential accumulation of alphaTCR with less mannose residues, suggesting its retention within the ER. Mass spectrometric analysis of cellular N-linked glycans revealed that depletion of VCP decreases the level of high-mannose glycoproteins, increases the levels of truncated low-mannose glycoproteins and induces changes in the abundance of complex glycans assembled in post-ER compartments. Since proteasome inhibition was unable to mimic those changes, they cannot be regarded as a simple consequence of inhibited ERAD but represent a complex effect of VCP on the function of the ER.

Laser-induced photofragmentation of neutral and acidic glycans inside an ion-trap mass spectrometer.

Permethylated acidic and neutral N-glycans representing different types of glycan structures, such as linear and branched sialylated structures, high-mannose type and fucosylated complex type, were photodissociated with 157 nm vacuum ultraviolet light in a linear ion trap. Cross-ring fragments corresponding to high-energy fragmentation pathways were observed in abundance for all studied structures. Some product ions appear diagnostic for a linkage of sialic acid residues and the glycan antenna to which these residues are attached. A conclusive assignment of the fucosylation site of the studied glycan structure has been facilitated through measurement of cross-ring fragmentation resulting from photodissociation.

Differentiating structural isomers of sialylated glycans by matrix-assisted laser desorption/ionization time-of-flight/time-of-flight tandem mass spectrometry.

Using model acidic glycans, we demonstrate the benefits of permethylation for matrix-assisted laser desorption/ionization time-of-flight/time-of-flight (MALDI/TOF-TOF) tandem mass spectrometry. With both the linear and branched structures, extensive cross-ring fragmentation product ions were generated, yielding valuable information on sugar linkages. Elimination of the negative charges commonly associated with sialylated structures through permethylation allowed their structural analysis in the positive ion mode. Extensive A- and X-type ions were observed for the linear structures, and slightly weaker signals for the branched sialylated structures. The diagnostic cross-ring fragments, permitting a distinction between alpha2-3 and alpha2-6 linkages of the sialic acid residues, were seen in abundance. Importantly, the cross-ring fragmentation with the branched structures provides adequate information to assign sialic acid residues, with a specific linkage, to a particular antenna.

Solid-phase permethylation of glycans for mass spectrometric analysis.

A miniaturized approach was developed for quantitative permethylation of oligosaccharides, which involves packing of sodium hydroxide powder in microspin columns or fused-silica capillaries (500 microm i.d.), permitting effective derivatization in less than a minute at microscale. Prior to mass spectrometry, analytes are mixed with methyl iodide in dimethyl sulfoxide solution containing traces of water before infusing through the microreactors. This procedure minimizes oxidative degradation and peeling reactions and avoids the need of excessive clean-up. Picomole amounts of linear and branched, sialylated and neutral glycan samples were rapidly and efficiently permethylated by this approach and analyzed by matrix-assisted laser desorption/ionization mass spectrometry.