Deglycosylation of asparagine-linked glycans by peptide:N-glycosidase F

Endo-beta-N-acetylglucosaminidase F (Endo F) and peptide:N-glycosidase F (PNGase F) were purified from cultures of Flavobacterium meningosepticum by ammonium sulfate precipitation followed by gel filtration on TSK HW-55(S). This system separated the two enzymes and provided PNGase F in a high state of purity, but the basis for the resolution appeared to be hydrophobic interaction and not molecular size. Studies using purified Endo F and PNGase F with defined glycopeptides demonstrated that Endo F was somewhat similar to Endo H in that it hydrolyzed many, but not all, high-mannose and hybrid oligosaccharides, as well as complex biantennary oligosaccharides. PNGase F, in contrast, hydrolyzed all classes of asparagine-linked glycans examined, provided both the alpha-amino and carboxyl groups of the asparagine residue were in peptide linkage. Deglycosylation studies with PNGase F revealed that many proteins in their native conformation were susceptible to this enzyme but that prior denaturation in sodium dodecyl sulfate greatly decreased the amount of enzyme required for complete carbohydrate removal.     

Specificity of enzymatic in vitro glycosylation by PNGase F: a comparison of enzymatic and non-enzymatic glycosylation

Enzymatic in vitro glycosylation is possible using a reverse reaction of peptide-N-glycosidase F (PNGase F), and non-enzymatic in vitro glycosylation occurs when the sugar residue is one or two units long. To identify the differences between enzymatic and non-enzymatic glycosylation, glycosylation sites were analyzed by the acid hydrolysis of glycopeptides followed by MALDI-TOF mass spectrometric analysis. Pentapeptide (Arg-Lys-Asp-Val-Tyr) and octapeptide (Glu-Ile-Leu-Asp-Val-Pro-Ser-Thr) were used in this study, and the sequence of the octapeptide was appropriately chosen to investigate the specificity of enzymatic glycosylation by considering the characteristics of PNGase F and non-enzymatic glycosylation. N,N′-Diacetylchitobiose was aminated prior to the glycosylation reaction at an amination extent of 60%. The glycosylation site was very specific to the aspartate residue in the enzymatic reaction, while non-enzymatic glycosylation occurred at arginine or lysine residues. PNGases F can be effectively used for the glycosylation of the non-glycosylated recombinant proteins produced in prokaryotic cells.     

Identification of deamidation and isomerization sites on pharmaceutical recombinant antibody using H(2)(18)O

Asparagine (Asn) deamidation and aspartic acid (Asp) isomerization are spontaneous and common alterations occurring in pharmaceutical protein drugs in solution. Because those reactions may cause functional changes, it is important to identify the product-related substances, especially when biopharmaceuticals are under development. In this study, we used H(2)(18)O to identify Asn deamidation and Asp isomerization sites on a recombinant humanized monoclonal antibody (mAb) by using high-performance liquid chromatography-mass spectrometry (HPLC-MS). This strategy takes advantage of reactions whereby (18)O is incorporated into the protein molecule. The mAb was lyophilized and reconstituted in H(2)O or H(2)(18)O, followed by incubation at 50 degrees C for 1 month. Samples were reduced/carboxymethylated and digested by trypsin and then subjected to HPLC-MS and HPLC-tandem mass spectrometry (MS/MS) analysis. Among all of the peptide fragments analyzed, there were two in which deamidation and/or isomerization was observed. In one peptide fragment, an obvious mass shift ( approximately 3Da) at Asn was observed in the newly produced peptide when the mAb was incubated in H(2)(18)O, whereas it was barely feasible to identify this mass shift in H(2)O. In the other peptide fragment, isomerization of Asp was identified after incubation in H(2)(18)O, although it was impossible to distinguish when using H(2)O. By means of this procedure, identification of deamidation and isomerization sites can be accomplished easily even when they are difficult or impossible to detect by the usual peptide mapping.     

An enzymatic deglycosylation scheme enabling identification of core fucosylated N-glycans and O-glycosylation site mapping of human plasma proteins

Global proteome analysis of protein glycosylation is a major challenge due to the inherent heterogeneous and diverse nature of this post-translational modification. It is therefore common to enzymatically remove glycans attached to protein or peptide chains prior to mass spectrometric analysis, thereby reducing the complexity and facilitating glycosylation site determinations. Here, we have used two different enzymatic deglycosylation strategies for N-glycosylation site analysis. (1) Removal of entire N-glycan chains by peptide-N-glycosidase (PNGase) digestion, with concomitant deamidation of the released asparagine residue. The reaction is carried out in H218O to facilitate identification of the formerly glycosylated peptide by incorporatation of 18O into the formed aspartic acid residue. (2) Digestion with two endo-beta-N-acetylglucosaminidases (Endo D and Endo H) that cleave the glycosidic bond between the two N-acetylglucosamine (GlcNAc) residues in the conserved N-glycan core structure, leaving single GlcNAc residues with putative fucosyl side chains attached to the peptide. To enable digestion of complex and hybrid type N-glycans, a number of exoglycosidases (beta-galactosidase, neuraminidase and N-acetyl-beta-glucosaminidase) are also included. The two strategies were here applied to identify 103 N-glycosylation sites in the Cohn IV fraction of human plasma. In addition, Endo D/H digestion uniquely enabled identification of 23 fucosylated N-glycosylation sites. Several O-glycosylated peptides were also identified with a single N-acetylhexosamine attached, arguably due to partial deglycosylation of O-glycan structures by the exoglycosidases used together with Endo D/H.     

Chemical deamidation: a common pitfall in large-scale N-linked glycoproteomic mass spectrometry-based analyses

N-Linked glycoproteins are involved in several diseases and are important as potential diagnostic molecules for biomarker discovery. Therefore, it is important to provide sensitive and reliable analytical methods to identify not only the glycoproteins but also the sites of glycosylation. Recently, numerous strategies to identify N-linked glycosylation sites have been described. These strategies have been applied to cell lines and several tissues with the aim of identifying many hundreds (or thousands) of glycosylation events. With high-throughput strategies however, there is always the potential for false positives. The confusion arises since the protein N-glycosidase F (PNGase F) reaction used to separate N-glycans from formerly glycosylated peptides catalyzes the cleavage and deamidates the asparagine residue. This is typically viewed as beneficial since it acts to highlight the modification site. We have evaluated this common large-scale N-linked glycoproteomic strategy and proved potential pitfalls using Escherichia coli as a model organism, since it lacks the N-glycosylation machinery found in mammalian systems and some pathogenic microbes. After isolation and proteolytic digestion of E. coli membrane proteins, we investigated the presence of deamidated asparagines. The results show the presence of deamidated asparagines especially with close proximity to a glycine residue or other small amino acid, as previously described for spontaneous in vivo deamidation. Moreover, we have identified deamidated peptides with incorporation of (18)O, showing the pitfalls of glycosylation site assignment based on deamidation of asparagine induced by PNGase F in (18)O-water in large-scale analyses. These data experimentally prove the need for more caution in assigning glycosylation sites and "new" N-linked consensus sites based on common N-linked glycoproteomics strategies without proper control experiments. Besides showing the spontaneous deamidation, we provide alternative methods for validation that should be used in such experiments.     

A method for determination of N-glycosylation sites in glycoproteins by collision-induced dissociation analysis in fast atom bombardment mass spectrometry: identification of the positions of carbohydrate-linked asparagine in recombinant alpha-amylase by treatment with peptide-N-glycosidase F in 18O-labeled water.

Previously, a combined use of fast atom bombardment (FAB) mass spectrometry and peptide N-glycosidase F, an enzyme that cleaves the beta-aspartylglycosylamine linkage of Asn-linked carbohydrates, was successfully applied to identification of N-glycosylation sites in a glycoprotein with the known or DNA-derived sequence (S. A. Carr and G. D. Roberts, 1986, Anal. Biochem. 157, 396-406). Here, we extended the method for easier identification of N-glycosylation sites in a glycoprotein even with unknown sequence. The glycoprotein is digested with peptide-N-glycosidase F in buffer containing 40 at% H2 18O, to yield a deglycosylated protein whose carbohydrate-linked Asn residues are converted to Asp partly labeled with 18O at their beta-carboxyl group during this digestion. The deglycosylated protein is further digested with proteolytic enzymes in an appropriate buffer prepared with normal water, and then peptides are separated on a reversed-phase column by HPLC. Peptides in which carbohydrate-linked Asn has been converted to Asp show a pair of signals ([M + 1]+ and [M + 3]+) in FAB mass spectra due to the partial incorporation of 18O into the beta-carboxyl groups of Asp residues, while the other peptides show normal isotopic ion distributions. Thus, both formally N-glycosylated peptides and, using collision-induced dissociation analysis, N-glycosylation sites can be identified. The application of the present method to the determination of N-glycosylation sites in a recombinant glycoprotein, Bacillus licheniformis alpha-amylase, is described.     

Human urinary glycoproteomics; attachment site specific analysis of N- and O-linked glycosylations by CID and ECD

Urine is a complex mixture of proteins and waste products and a challenging biological fluid for biomarker discovery. Previous proteomic studies have identified more than 2800 urinary proteins but analyses aimed at unraveling glycan structures and glycosylation sites of urinary glycoproteins are lacking. Glycoproteomic characterization remains difficult because of the complexity of glycan structures found mainly on asparagine (N-linked) or serine/threonine (O-linked) residues. We have developed a glycoproteomic approach that combines efficient purification of urinary glycoproteins/glycopeptides with complementary MS-fragmentation techniques for glycopeptide analysis. Starting from clinical sample size, we eliminated interfering urinary compounds by dialysis and concentrated the purified urinary proteins by lyophilization. Sialylated urinary glycoproteins were conjugated to a solid support by hydrazide chemistry and trypsin digested. Desialylated glycopeptides, released through mild acid hydrolysis, were characterized by tandem MS experiments utilizing collision induced dissociation (CID) and electron capture dissociation fragmentation techniques. In CID-MS(2), Hex(5)HexNAc(4)-N-Asn and HexHexNAc-O-Ser/Thr were typically observed, in agreement with known N-linked biantennary complex-type and O-linked core 1-like structures, respectively. Additional glycoforms for specific N- and O-linked glycopeptides were also identified, e.g. tetra-antennary N-glycans and fucosylated core 2-like O-glycans. Subsequent CID-MS(3), of selected fragment-ions from the CID-MS(2) analysis, generated peptide specific b- and y-ions that were used for peptide identification. In total, 58 N- and 63 O-linked glycopeptides from 53 glycoproteins were characterized with respect to glycan- and peptide sequences. The combination of CID and electron capture dissociation techniques allowed for the exact identification of Ser/Thr attachment site(s) for 40 of 57 putative O-glycosylation sites. We defined 29 O-glycosylation sites which have, to our knowledge, not been previously reported. This is the first study of human urinary glycoproteins where "intact" glycopeptides were studied, i.e. the presence of glycans and their attachment sites were proven without doubt.     

Structural fingerprinting of Asn-linked carbohydrates from specific attachment sites in glycoproteins by mass spectrometry: application to tissue plasminogen activator

A sensitive and specific strategy has been developed for determining the sites of attachment of Asn-linked carbohydrates in glycoproteins, and defining the compositions and molecular heterogeneity of carbohydrates at each specific attachment site. In this carbohydrate 'fingerprinting' strategy, potential glycopeptides are identified by comparing the high pressure liquid chromatography (HPLC) chromatograms of proteolytic digests of a glycoprotein obtained before and after digestion with a glycosidase, usually peptide:N-glycosidase F (PNGase F). The glycopeptide-containing HPLC fractions are analyzed by fast atom bombardment mass spectrometry (FAB MS) prior to and after digestion with PNGase F to identify the former glycosylation site peptide and its sequence location (Carr and Roberts, (1986) Anal. Biochem. 157, 396-406). Carbohydrates are extracted from these fractions as the peracetates which are then permethylated and analyzed by FAB MS. The spectra exhibit molecular weight-related ions for each of the parent oligosaccharides present in the fraction which provide composition in terms of hexose, deoxyhexose, N-acetylhexosamine and sialic acid. The relative ratios of these peaks reflect the relative abundances of the various carbohydrate homologs present in the mixture. The derivatives formed are directly amenable to methylation analysis for determination of linkage. This strategy enables the structural classes of carbohydrates at specific attachment sites to be determined using only a few nmol of glycoprotein. The carbohydrate fingerprinting strategy has been applied to a number of glycoproteins including tissue plasminogen activator, the results for which are described herein.     

Assay of glycoamidases and endo-beta-N-acetylglucosaminidases by lectin capture and dissociation-enhanced lanthanide fluorescence immunoassay

We have developed an assay system for endo-beta-N-acetylglucosaminidase and glycoamidase (PNGase), using Eu(3+)-labeled Man(9)GlcNAc(2) glycopeptides as substrates in combination with lectin capture. Two glycopeptides of different peptide lengths, derived from soybean agglutinin, were labeled with Eu(3+) via a diethylenetriaminepentaacetate (DTPA) chelating linker and served as substrates for two types of enzymes: one with (Man(9)GlcNAc(2))Asn for endo-beta-N-acetylglucosaminidase and the other with Ala-Ser-Phe-(Man(9)GlcNAc(2))Asn-Phe-Thr for glycoamidase activities. Following enzymatic hydrolysis, concanavalin A, immobilized or soluble, was added to the mixture to bind unreacted substrate and unlabeled hydrolysis product. The labeled peptide product could then be separated from the lectin-bound complexes by filtration for quantification by dissociation-enhanced lanthanide fluorescence immunoassay. Activities as low as 2 fmol min(-1) could be rapidly quantified for both types of enzymes, and enzymological parameters could be determined within minutes. Applicability of the assay was tested for identification of a glycoamidase activity peak in the fractionation of sweet almond emulsin, a classic example. This assay offers sensitivity, ease of use, and high throughput. In addition, it is versatile and should be applicable to other glycobiology enzyme systems.     

Determination of the disulfide bond arrangement of dengue virus NS1 protein

The 12 half-cystines of NS1 proteins are absolutely conserved among flaviviruses, suggesting their importance to the structure and function of these proteins. In the present study, peptides from recombinant Dengue-2 virus NS1 were produced by tryptic digestion in 100% H(2)(16)O, peptic digestion in 50% H(2)(18)O, thermolytic digestion in 50% H(2)(18)O, or combinations of these digestion conditions. Peptides were separated by size exclusion and/or reverse phase high performance liquid chromatography and examined by matrix-assisted laser desorption ionization-time of flight mass spectrometry, matrix-assisted laser desorption ionization post-source decay, and matrix-assisted laser desorption ionization tandem mass spectrometry. Where digests were performed in 50% H(2)(18)O, isotope profiles of peptide ions aided in the identification and characterization of disulfide-linked peptides. It was possible to produce two-chain peptides containing C1/C2, C3/C4, C5/C6, and C7/C12 linkages as revealed by comparison of the peptide masses before and after reduction and by post-source decay analysis. However, the remaining four half-cystines (C8, C9, C10, and C11) were located in a three-chain peptide of which one chain contained adjacent half-cystines (C9 and C10). The linkages of C8/C10 and C9/C11 were determined by tandem mass spectrometry of an in-source decay fragment ion containing C9, C10, and C11. This disulfide bond arrangement provides the basis for further refinement of flavivirus NS1 protein structural models.     

Staggered molecular packing in crystals of a collagen-like peptide with a single charged pair

The crystal structure of the triple-helical peptide, (Pro-Hyp-Gly)(4)-Glu-Lys-Gly-(Pro-Hyp-Gly)(5) has been determined to 1.75 A resolution. This peptide was designed to examine the effect of a pair of adjacent, oppositely charged residues on collagen triple-helical conformation and intermolecular interactions. The molecular conformation (a 7(5) triple helix) and hydrogen bonding schemes are similar to those previously reported for collagen triple helices and provides a second instance of water mediated N--H . . . O==C interchain hydrogen bonds for the amide group of the residue following Gly. Although stereochemically capable of forming intramolecular or intermolecular ion pairs, the lysine and glutamic acid side-chains instead display direct interactions with carbonyl groups and hydroxyproline hydroxyl groups or interactions mediated by water molecules. Solution studies on the EKG peptide indicate stabilization at neutral pH values, where both Glu and Lys are ionized, but suggest that this occurs because of the effects of ionization on the individual residues, rather than ion pair formation. The EKG structure suggests a molecular mechanism for such stabilization through indirect hydrogen bonding. The molecular packing in the crystal includes an axial stagger between molecules, reminiscent of that observed in D-periodic collagen fibrils. The presence of a Glu-Lys-Gly triplet in the middle of the sequence appears to mediate this staggered molecular packing through its indirect water-mediated interactions with backbone C==O groups and side chains.     

Glycoproteomics of Trypanosoma cruzi trypomastigotes using subcellular fractionation, lectin affinity, and stable isotope labeling

Herein we detail the first glycoproteomic analysis of a human pathogen. We describe an approach that enables the identification of organelle and cell surface N-linked glycoproteins from Trypanosoma cruzi, the causative agent of Chagas' disease. This approach is based on a subcellular fractionation protocol to produce fractions enriched in either organelle or plasma membrane/cytoplasmic proteins. Through lectin affinity capture of the glycopeptides from each subcellular fraction and stable isotope labeling of the glycan attachment sites with H(2)18O, we unambiguously identified 36 glycosylation sites on 35 glycopeptides which mapped to 29 glycoproteins. We also present the first expression evidence for 11 T. cruzi specific glycoproteins and provide experimental data indicating that the mucin associated surface protein family (MASP) and dispersed gene family (DGF-1) are post-translationally modified by N-linked glycans.     

A novel quantitative proteomics workflow by isobaric terminal labeling

Quantification by series of b, y fragment ion pairs generated from isobaric-labeled peptides in MS2 spectra has recently been considered an accurate strategy in quantitative proteomics. Here we developed a novel MS2 quantification approach named quantitation by isobaric terminal labeling (QITL) by coupling (18)O labeling with dimethylation. Trypsin-digested peptides were labeled with two (16)O or (18)O atoms at their C-termini in H(2)(16)O or H(2)(18)O. After blocking all ε-amino groups of lysines through guanidination, the N-termini of the peptides were accordingly labeled with formaldehyde-d(2) or formaldehyde. These indistinguishable, isobaric-labeled peptides in MS1 spectra produce b, y fragment ion pairs in the whole mass range of MS2 spectra that can be used for quantification. In this study, the feasibility of QITL was first demonstrated using standard proteins. An accurate and reproducible quantification over a wide dynamic range was achieved. Then, complex rat liver samples were used to verify the applicability of QITL for large-scale quantitative analysis. Finally, QITL was applied to profile the quantitative proteome of hepatocellular carcinoma (HCC) and adjacent non-tumor liver tissues. Given its simplicity, low-cost, and accuracy, QITL can be widely applied in biological samples (cell lines, tissues, and body fluids, etc.) for quantitative proteomic research.     

Identification of the interactions between cytochrome P450 2E1 and cytochrome b5 by mass spectrometry and site-directed mutagenesis

The reaction cycles of cytochrome P450s (P450) require input of two electrons. Electrostatic interactions are considered important driving forces in the association of P450s with their redox partners, which in turn facilitates the transfer of the two electrons. In this study, the cross-linking reagent, 1-ethyl-3-[3-dimethylaminopropyl]carbodiimide hydrochloride (EDC), was used to covalently link cytochrome P450 2E1 (CYP2E1) with cytochrome b(5) (b(5)) through the formation of specific amide bonds between complementary charged residue pairs. Cross-linked peptides in the resulting protein complex were distinguished from non-cross-linked peptides using an (18)O-labeling method on the basis that cross-linked peptides incorporate twice as many (18)O atoms as non-cross-linked peptides during proteolysis conducted in (18)O-water. Subsequent tandem mass spectrometric (MS/MS) analysis of the selected cross-linked peptide candidates led to the identification of two intermolecular cross-links, Lys(428)(CYP2E1)-Asp(53)(b(5)) and Lys(434)(CYP2E1)-Glu(56)(b(5)), which provides the first direct experimental evidence for the interacting orientations of a microsomal P450 and its redox partner. The biological importance of the two ion pairs for the CYP2E1-b(5) interaction, and the stimulatory effect of b(5), was confirmed by site-directed mutagenesis. Based on the characterized cross-links, a CYP2E1-b(5) complex model was constructed, leading to improved insights into the protein interaction. The described method is potentially useful for mapping the interactions of various P450 isoforms and their redox partners, because the method is relatively rapid and sensitive, and is capable of suggesting not only protein interacting regions, but also interacting orientations.     

Kinetic comparison of peptide: N-glycosidases F and A reveals several differences in substrate specificity

The initial velocities of hydrolysis of nineteen glycopeptides by peptide: N-glycosidase F and A were determined. Substrates were prepared from bovine fetuin, hen ovalbumin, pineapple stem bromelain, bovine fibrin and taka-amylase. From these glycopeptides, several variants with regard to peptide and carbohydrate structure were prepared and derivatized with dabsyl chloride, dansyl chloride or activated resorufin. Tyrosine containing glycopeptides were also used without an additional chromophore. Enzymatic hydrolysis of glycopeptides was quantified by narrow bore, reversed phase HPLC with turnaround cycle times of down to 6 min, but usually 15 min.K _M values ranging from 30 to 64 µm and from 4 to 36 µm were found for N-glycosidase F and A, respectively. Relative velocities of hydrolysis of the different substrates by each enzyme varied considerably. Little, if any, similarity of the performance of N-glycosidase F and A with the different substrates was observed. The minimal carbohydrate structure released by peptide: N-glycosidase F was a di-N-acetylchitobiose. N-glycosidase A could release even a singleN-acetylglucosamine, albeit 3000 times slower than a di-N-acetylchitobiose or larger glycans. In general the structure of the intact glycan had little effect on activity, and with both enzymes the rate of hydrolysis appeared to be primarily governed by peptide structure and length. However, N-glycosidase F did not release glycans 1,3-fucosylated at the asparagine linkedN-acetylglucosamine irrespective of the presence of xylose in the substrate.Abbreviations CAMCys S-carboxamidomethyl cystein - CMCys S-carboxymethyl cystein - Fib, Fet, Ova, Taa and Brl glycopeptides derived from bovine fibrin, fetuin, ovalbumin, taka-amylase A, and bromelain, respectively - GlcNAc N-acetylglucosamine - PLA phospholipase A₂ - PNGase peptide N-glycosidase - RESOS N-(Resorufin-4-carbonyl)piperidine-4-carboxylic acidN-hydroxysuccinimide ester     

Identification of glycan structure and glycosylation sites in cellobiohydrolase II and endoglucanases I and II from Trichoderma reesei

Mass spectrometric techniques combined with enzymatic digestions were applied to determine the glycosylation profiles of cellobiohydrolase (CBH II) and endoglucanases (EG I, II) purified from filamentous fungus Trichoderma reesei. Electrospray mass spectrometry (ESMS) analyses of the intact cellulases revealed the microheterogeneity in glycosylation where glycoforms were spaced by hexose units. These analyses indicated that glycosylation accounted for 12-24% of the molecular mass and that microheterogeneity in both N- and O-linked glycans was observed for each glycoprotein. The identification of N-linked attachment sites was carried out by MALDI-TOF and capillary liquid chromatography-ESMS analyses of tryptic digests from each purified cellulase component with and without PNGase F incubation. Potential tryptic glycopeptide candidates were first detected by stepped orifice-voltage scanning and the glycan structure and attachment site were confirmed by tandem mass spectrometry. For purified CBH II, 74% of glycans found on Asn310 were high mannose, predominantly Hex(7-9)GlcNAc(2), whereas the remaining amount was single GlcNAc; Asn289 had 18% single GlcNAc occupancy, and Asn14 remained unoccupied. EG I presented N-linked glycans at two out of the six potential sites. The Asn56 contained a single GlcNAc residue, and Asn182 showed primarily a high-mannose glycan Hex(8)GlcNAc(2) with only 8% being occupied with a single GlcNAc. Finally, EG II presented a single GlcNAc residue at Asn103. It is noteworthy that the presence of a single GlcNAc in all cellulase enzymes investigated and the variability in site occupancy suggest the secretion of an endogenous endo H enzyme in cultures of T. reesei.     

Identification and Characterization of a Novel Prokaryotic Peptide: N-GLYCOSIDASE FROM ELIZABETHKINGIA MENINGOSEPTICA*

Peptide:N-glycosidase (PNGase) F, the first PNGase identified in prokaryotic cells, catalyzes the removal of intact asparagine-linked oligosaccharide chains from glycoproteins and/or glycopeptides. Since its discovery in 1984, PNGase F has remained as the sole prokaryotic PNGase. Recently, a novel gene encoding a protein with a predicted PNGase domain was identified from a clinical isolate of Elizabethkingia meningoseptica. In this study, the candidate protein was expressed in vitro and was subjected to biochemical and structural analyses. The results revealed that it possesses PNGase activity and has substrate specificity different from that of PNGase F. The crystal structure of the protein was determined at 1.9 Å resolution. Structural comparison with PNGase F revealed a relatively larger glycan-binding groove in the catalytic domain and an additional bowl-like domain with unknown function at the N terminus of the candidate protein. These structural and functional analyses indicated that the candidate protein is a novel prokaryotic N-glycosidase. The protein has been named PNGase F-II.     

Identification of isomerization and racemization of aspartate in the Asp-Asp motifs of a therapeutic protein

A thermally stressed Fab molecule showed a significant increase of basic variants in imaged capillary isoelectric focusing (iCIEF) analysis. Mass analyses of the reduced protein found an increase in −18 Da species from both light chain and heavy chain. A tryptic peptide map identified two isoAsp-containing peptides, both containing Asp–Asp motifs and located in complementarity-determining regions (CDRs) of light chains and heavy chains, respectively. The approaches of hydrolyzing succinimide in H₂¹⁸O followed by tryptic digestion were used to label and identify the sites of isomerization. This method enabled identification of the isomerization site by comparing the MS/MS spectra of isomerized peptides with and without ¹⁸O incorporation. The light chain peptide L2 VTITCITSTDID₁₂DDMNWYQQKPGK underwent simultaneous isomerization and recemization at residue Asp-12 after thermal stress as evidenced by the coinjection of synthetic peptide L2 with l-Asp-12, l-isoAsp-12, d-Asp-12, and d-isoAsp-12, respectively. A thermal stress study of the synthetic peptide (l-)L2 showed that the isomerization and racemization did not occur, indicating that the Asp degradation in this Asp–Asp motif is more related to the protein conformation than the primary sequence. Another isomerization site was identified as Asp-24 in the heavy chain peptide H5 QAPGQGLEWMGWINTYTGETTYAD₂₄DFK. No other isomerizations were detected in CDR peptides containing either Asp–Ser or Asp–Thr motifs.     

Oxygen exchange between acetate and the catalytic glutamate residue in glutaconate CoA-transferase from Acidaminococcus fermentans. Implications for the mechanism of CoA-ester hydrolysis.

The exchange of oxygen atoms between acetate, glutaryl-CoA, and the catalytic glutamate residue in glutaconate CoA-transferase from Acidaminococcus fermentans was analyzed using [(18)O(2)]acetate together with matrix-assisted laser desorption/ionization time of flight mass spectrometry of an appropriate undecapeptide. The exchange reaction was shown to be site-specific, reversible, and required both glutaryl-CoA and [(18)O(2)]acetate. The observed exchange is in agreement with the formation of a mixed anhydride intermediate between the enzyme and acetate. In contrast, with a mutant enzyme, which was converted to a thiol ester hydrolyase by replacement of the catalytic glutamate residue by aspartate, no (18)O uptake from H(2)(18)O into the carboxylate was detectable. This result is in accord with a mechanism in which the carboxylate of aspartate acts as a general base in activating a water molecule for hydrolysis of the thiol ester intermediate. This mechanism is further supported by the finding of a significant hydrolyase activity of the wild-type enzyme using acetyl-CoA as substrate, whereas glutaryl-CoA is not hydrolyzed. The small acetate molecule in the substrate binding pocket may activate a water molecule for hydrolysis of the nearby enzyme-CoA thiol ester.     

Analysis of PNGase F‐Resistant N‐Glycopeptides Using SugarQb for Proteome Discoverer 2.1 Reveals Cryptic Substrate Specificities

SugarQb ( www.imba.oeaw.ac.at/sugarqb ) is a freely available collection of computational tools for the automated identification of intact glycopeptides from high‐resolution HCD MS/MS datasets in the Proteome Discoverer environment. We report the migration of SugarQb to the latest and free version of Proteome Discoverer 2.1, and apply it to the analysis of PNGase F‐resistant N‐glycopeptides from mouse embryonic stem cells. The analysis of intact glycopeptides highlights unexpected technical limitations to PNGase F‐dependent glycoproteomic workflows at the proteome level, and warrants a critical reinterpretation of seminal datasets in the context of N‐glycosylation‐site prediction.