be INSPIRED drive DISCOVERY stay GENUINE APPLICATION NOTE Detailed Characterization of Antibody Glycan Structure using the N-Glycan Sequencing Kit Beth McLeod, New England Biolabs, Inc. Materials Remicade (Infliximab) from Imclone, LLC Enbrel (entanercept) from Amgen Inc., manufactured by Immunex Corp Rapid PNGase F (NEB #P71) N-Glycan Sequencing Kit (NEB #E577) α2-3,6,8,9 Neuraminidase A (NEB #P722) Introduction Characterization of glycans on therapeutic IgGs is critical as the stability, half-life, and clinical efficacy are affected by the glycoforms present on the molecule. The inherent complexity of protein glycosylation poses a daunting analytical challenge. Multiple orthogonal methods are often used to elucidate structure, but even with techniques such as LC-MS, which has the advantage of an associated mass corresponding to each chromatographic peak, there can be ambiguities when assigning structures. There are often several possible glycan isoforms associated with an identical mass. The use of sequential exoglycosidase digestion of oligosaccharides followed by LC-MS or CE analysis provides detailed carbohydrate sequence information and resolves ambiguities. Highly specific exoglycosidases cleave monosaccharides from the non-reducing end of an oligosaccharide and can yield information about the linkage, stereochemistry and configuration of the anomeric carbon. Enzymes can be used in various combinations to simplify glycan profiles and highlight the overall level of a specific epitope. An example is fucosylation, which can potentially influence antibody-dependent, cell-mediated cytotoxicity (ADCC)(1). Exoglycosidases can be used in combination to trim the glycan to the trimannosyl core, with or without fucose. Multiple digestions reduce complex data to a simplified panel that can be more easily quantitated. Mannosidases, such as α1-2,3,6 Mannosidase (NEB #P768) can be used to monitor the ratio of high mannose in a glycan profile, an epitope that can lead to a higher clearance rate of a given therapeutic(2). Neuraminidases, such as α2-3,6,8,9 Neuraminidase A (NEB #P722) and galactosidases such as α1-3,4,6 Galactosidase (NEB #P747), can be used to monitor the presence of N-glycolylneuraminic acid (Neu5Gc) and alpha-linked galactose residues, potentially immunogenic, non-human epitopes that are present in murine derived antibodies. Here we used the N-Glycan Sequencing Kit, which contains seven of the most commonly used exoglycosidases for N-Glycan sequencing, to precisely characterize glycans on the Fc domain of therapeutic antibodies and dimeric fusion proteins. The workflow described includes glycan release with Rapid PNGase F (NEB #P71), direct labelling of released glycans with procainamide (PCA) or 2-aminobenzamide (2AB), clean-up of labeled glycans and a 3 hour enzymatic digestion with exoglycosidases. This protocol is designed for completion within an 8 hour time frame to allow for subsequent LC or LC-MS analysis overnight. Glycan Sample Preparation Workflow: Deglycosylation 1 minutes PCA or 2AB Labeling 45 minutes FIGURE 1: Infliximab and Enbrel Structures HILIC Clean Up 2 minutes α1-3,4,6 Galactosidase (NEB #P747) β1-4 Galactosidase S (NEB #P745) β-n-acetylglucosaminidase S (NEB #P744) α1-2,4,6 Fucosidase O (NEB #P749) α1-2,3,6 Mannosidase (NEB #P768) HILIC Plate: The Nest Group, Inc. part #SNS-HiL HILIC Microspin Column: The Nest Group Inc. part #SEM HiL Procainamide (PCA) (Sigma P9391) 2-aminobenzamide (2AB) (Sigma A8984) Sodium cyanoborohydride (Sigma 156159) Dimethyl sulfoxide (DMSO) Glacial Acetic Acid Acetonitrile (ACN) HLPC/MS grade 5 mm NH 4 Formate Buffer (ph 4.4) Dry Glycans 3 mins-1.5 hrs A. Infliximab chimeric antibody B. Enbrel fusion protein Exoglycosidase Digestion 3 hours 1/18 1
FIGURE 2: Infliximab glycan profile A. Infliximab chimeric antibody 1 95 9 85 8 75 7 65 6 14.24 Exoglycosidases are used to resolve assignment of peak with corresponding m/z value of 14.24. α2-3,6,8,9 Neuraminidase A, α1-3,4,6 Galactosidase, and β1-4 Galactosidase S are used to digest the substrate. Disappearance of the peak with β1-4 Galactosidase S indicates the correct structure among the three possible glycoforms. Relative Abundance 55 5 45 4 35 3 25 2 15 1 5 55.75 61.28 78.7 168.86 191.76 528.73 1192.57 148.82 91.77 848.85 1386.57 4 6 8 1 12 14 16 18 2 m/z 1641.81 1713.7 1813.24 1976.47 A 16.94 Possible structures with m/z at or close to 14 8 6 4 22.13 2 22.97 18.83 19.72 24.52 28.83 26.7 3.99 33.85 35.28 36.64 B 16.98 8 6 4 22.18 Panel B treated with 2 μl of α2-3,6,8,9 Neuraminidase A (NEB #P722) 2 19.76 23.2 18.86 28.89 25. 26.15 31.46 32.26 34.5 35.98 C 8 16.97 6 4 22.19 Panel C treated with 1 μl of α1-3,4,6 Galactosidase (NEB #P747) D 2 15 17.1 19.77 23.4 18.87 28.93 25.1 25.58 31.51 32.17 34.5 35.93 1 5 Panel D treated with 1 μl of β1-4 Galactosidase S (NEB #P745) 18.88 19.49 21.87 22.53 24.58 25.93 28.12 29.59 31.43 33.53 34.18 35.78 18 2 22 24 26 28 3 32 34 36 Disappearance of peak with β1-4 Galactosidase S allows assignment of glycan isomer. Gal Glc Man GalNAc GlcNAc Fuc NeuAc NeuGc 2
General Protocol Rapid Deglycosylation The antibody sample is treated with Rapid PNGase F using the two-step deglyosylation protocol 1. Using PCR tubes (2 μl), add 3 μg of monoclonal antibody (see Note 1) to a final volume of 16 μl 2. Add 4 μl Rapid PNGase F Buffer and mix 3. Incubate mixture at 8 C for 2 minutes and cool 4. Add 1 μl of Rapid PNGase F 5. Incubate for 1 minutes at 5 C in a thermocycler or heat block Fluorescent labeling with procainamide (PCA) or 2-aminobenzamide (2AB) 1. Add 18 μl of acidified PCA or 2AB labeling reagent (see Note 2) and 24 μl cyanoborohydride reagent to the deglycosylation reactions 2. Incubate for 45 minutes at 65 C in a thermocycler 3. Cool reactions to room temperature Glycan purification with a 96-well HILIC plate 1. Add 35 μl Acetonitrile (ACN) to the labeled reactions to a final concentration of 85% ACN 2. Set up a HILIC elution plate with shims or spacer and waste tray if necessary 3. Condition well with 2 μl of H 2 O 4. Equilibrate well with 2 μl of of 85% ACN 5. Load PCA or 2AB labeled samples diluted with ACN (~41 μl) onto the HILIC plate 6. Wash wells with 3 x 2 μl of 1% formic acid, 9% ACN 7. Replace waste tray with collection plate 8. Elute glycans with 3 x 3 μl of SPE buffer (see Note 3) into the collection plate 9. Dry the 9 μl sample in a speed vac or lyophilize overnight (see Note 4) 1. Resuspend the sample in 3 μl of H 2 O for subsequent exoglycosidase reactions TABLE 1: Exoglycosidase digestion panel Glycan Purification with a HILIC spin column 1. Add 35 μl Acetonitrile (ACN) to the labeled reactions for a final concentration of 85% ACN 2. Use either a vacuum manifold or centrifuge adaptor (following manufacturer s instructions), condition a HILIC spin column with 35 μl of water 3. Equilibrate column with 35 μl of 85% ACN 4. Load PCA labeled samples diluted with ACN onto the HILIC column 5. Wash column with 5 x 3 μl of 1% formic acid, 9% ACN 6. Elute glycans with 3 x 3 μl of SPE into a collection tube for a final volume of 9 μl 7. Dry the 9 μl sample in a speed vac at 35 C or lyophilize overnight (see Note 4) 8. Resuspend the sample in 3 μl of water for subsequent exoglycosidase reactions Digestion of PCA labeled glycans with exoglycosidases Exoglycosidases can be used in single digests or in combinations to elucidate information about the total glycan profile 1. In PCR tubes (2 μl), mix 5 μl of PCAlabeled N-glycans (equivalent to 5 μg of starting material) from previous step with 2 μl 1X Glycobuffer 1, the recommended volume of exoglycosidase (see Table 1) and water to a final reaction volume of 2 μl 2. Incubate reactions for 3 hrs at 37 C 3. Add 1 μl of 5 mm NH 4 Formate Buffer ph 4.4 and 9 μl acetonitrile to each 2 μl reaction for a final acetronitrile concentration of 7% 4. Samples are now ready for LC or LC-MS analysis. In this experiement, N-glycan samples were separated using a XBridge BEH Amide column (Waters) on a Dionex UltiMate LC equipped with fluorescent detection in line with a LTQ Orbitrap Velos Spectrometer equipped with a heated electrospray standard source (HESI-II probe) Notes Note 1: 2-AB labeled glycan signal is typically not as intense as PCA and may require more labeled substrate to get an adequate MS signal Note 2: Stock solutions of PCA (55 mg dissolved in 1 ml DMSO), 2AB (25 mg dissolved in 1 ml DMSO), and sodium cyanoborohydride (2 mg/ml H 2 O) can be kept at -2 C and thawed prior to use (reagents remain stable for several weeks and numerous freeze/ thaw cycles). Prepare acidifed PCA or 2-AB solution by adding one volume of glacial acetic acid to eight volumes of PCA or 2AB stock solution. Note 3: SPE buffer: 2 mm Ammonium Acetate Note 4: Samples eluted with SPE buffer can be aliquoted before using the speed vac to decrease drying time COMPONENT RXN 1 RXN 2 RXN 3 RXN 4 RXN 5 RXN 6 PCA-Labelled N-Glycans 5 μl 5 μl 5 μl 5 μl 5 μl 5 μl 1X Glycobuffer 1 2 μl 2 μl 2 μl 2 μl 2 μl 2 μl H 2 O 13 μl 11 μl 1 μl 9 μl 8 μl 6 μl α2-3,6,8,9 Neuraminidase A (NEB #P722) 2 μl 2 μl 2 μl 2 μl 2 μl α1-3,4,6 Galactosidase (NEB #P747) 1 μl 1 μl 1 μl 1 μl b1-4 Galactosidase S (NEB #P745) 1 μl 1 μl 1 μl β-n-acetylglucosaminidase S (NEB #P744) 1 μl 1 μl α1-2,4,6 Fucosidase O (NEB #P749) 2 μl Total 2 μl 2 μl 2 μl 2 μl 2 μl 2 μl 3
Results: FIGURE 3A: N-Glycans released from Infliximab, labeled with PCA, digested for 3 hours with exoglycosidases. Digestion of Infliximab with a sequential panel of exoglycosidases serves as a tool to elucidate and verify glycan profile. Refer to Table 1 for reaction conditions. See figure 3B below 16.94 Total glycan profile rxn 1 5 7.98 9.92 22.13 14.3 22.97 11.86 14.63 18.83 19.72 24.52 26.7 28.83 3.99 33.85 35.28 36.64 16.98 rxn 2 rxn 3 5 5 15 1 5 rxn 4 1 rxn 5 15 1 5 rxn 6 7.94 9.92 22.18 14.7 19.76 23.2 11.9 28.89 14.67 18.86 25. 26.15 31.46 32.26 34.5 37.17 16.97 22.19 14.4 19.77 23.4 28.93 7.91 9.87 11.87 14.64 18.87 25.1 31.51 34.5 35.93 37.55 17.1 14.9 7.93 9.94 11.92 14.68 18.88 21.87 24.58 25.93 28.12 29.92 31.43 34.18 35.78 11.4 9.35 13.18 15.48 16.34 18.86 21.51 22.63 24.71 26.31 28.12 28.92 31.37 34.9 35.73 37.54 9.41 8.2 1.4 13.21 14.12 16.79 18.88 19.7 23.94 24.68 26.36 28.8 3.86 32.2 34.99 35.81 1 15 2 25 3 35 37.5 37.49 α2-3,6,8,9 Neuraminidase A (NEB #P722) α2-3,6,8,9 Neuraminidase A (NEB #P722) α1-3,4,6 Galactosidase (NEB #P747) α2-3,6,8,9 Neuraminidase A (NEB #P722) α1-3,4,6 Galactosidase (NEB #P747) β1-4 Galactosidase S (NEB #P745) α2-3,6,8,9 Neuraminidase A (NEB #P722) α1-3,4,6 Galactosidase (NEB #P747) β1-4 Galactosidase S (NEB #P745) β-n-acetylglucosaminidase S (NEB #P744) α2-3,6,8,9 Neuraminidase A (NEB #P722) α1-3,4,6 Galactosidase (NEB #P747) β1-4 Galactosidase S (NEB #P745) β-n-acetylglucosaminidase S (NEB #P744) α1-2,4,6 Fucosidase O (NEB #P749) FIGURE 3B: Expanded lower abundance profile of Infliximab glycan analysis Region enlarged to see lower abundance glycans. Digestion with α2-3,6,8,9 Neuraminidase A and α1-3,4,6 Galactosidase facilitates assignment of low abundance, complex glycans. Gal Glc Man GalNAc GlcNAc Fuc NeuAc NeuGc 12 22.97 1 8 6 4 28.83 3.99 36.64 rxn 1 2 24.52 24.94 33.25 26.7 27.77 29.45 35.28 33.85 37.57 38.32 35.97 39.41 12 23.2 1 rxn 2 8 6 4 2 28.89 25. 31.46 34.5 24.57 26.15 29.44 35.98 37.17 27.77 32.26 37.49 39.22 α2-3,6,8,9 Neuraminidase A (NEB #P722) 12 23.4 rxn 3 1 8 6 4 2 24.63 25.1 28.93 31.51 25.58 26.68 29.62 32.11 34.5 35.93 37.55 39.4 24 26 28 3 32 34 36 38 4 α2-3,6,8,9 Neuraminidase A (NEB #P722) α1-3,4,6 Galactosidase (NEB #P747) 4
Quantification of specific isoforms can be difficult with a complex glycan panel, especially when looking for less abundant species or epitopes that coelute. This process can be simplified by digesting with exoglycosidase combinations that are selected to trim the panel down to simplified forms while highlighting the species of interest. In the experiment shown below in Figure 4, the glycan profile of Enbrel is reduced to three main peaks corresponding to high mannose, fucosylated and afucosylated species. These peaks are then easily integrated and quantitated. FIGURE 4: Glycans released from Enbrel, trimmed to trimannosyl core with exoglycosidases to quantitate overall level of fucosylation and high mannose structures. Panel A: Total glycan profile. Panel B: Enbrel glycan digestion with 2 μl of α2-3,6,8,9 Neuraminidase A, 1 μl of β1-4 Galactosidase S, and 1 μl of β-n-acetylglucosaminidase S. Panel C: Enbrel glycan digestion with 2 μl of α2-3,6,8,9 Neuraminidase A, 1 μl of β1-4 Galactosidase S, 1 μl of β-n-acetylglucosaminidase S, and 2 μl of α1-2,4,6 Fucosidase O. A 25 17.14 34. 2 36.36 15 1 22.38 31.57 B 5 1 1.1 11.46 14.26 23.22 29.1 35.37 19.6 28.54 14.8 26.24 19.81 38.53 8 6 4 9.56 Following digestion, high mannose and fucosylated epitopes are easily quantitated 2 13.65 15.54 18.95 21.64 25.4 27.68 29.67 31.41 35.25 39.31 C 9.56 12 1 8 Fucose residues are removed with α1-2,4,6 Fucosidase O 6 4 2 11.59 13.25 16.21 18.96 22.6 24.83 28.9 3.4 31.41 35.26 39.5 1 15 2 25 3 35 FIGURE 5: Quantitation of fucosylation and high mannose structures. % HIGH MANNOSE % FUCOSYLATION Man 4 Man 5 Fucosylated afucosylated 1.6 2.9 75.6 24.4 Gal Glc Man GalNAc GlcNAc Fuc NeuAc NeuGc 5
FIGURE 6: Enzyme combinations to help isolate and quantitate potentially immunogenic low abundance isotopes such as Neu5Gc and α1-3 Galactose in Infliximab, a murine-derived therapeutic. PANEL A: Total glycan profile. PANEL B: Infliximab glycan digestion with 1 μl of α1-3,4,6 Galactosidase, 1 μl of β1-4 Galactosidase S, and 1 μl of β-n-acetylglucosaminidase S. PANEL C: Infliximab glycan digestion with 2 μl of α2-3,6,8,9 Neuraminidase A, 1 μl of β1-4 Galactosidase S, and 1 μl of β-n-acetylglucosaminidase S. A 35 3 17.7 25 2 15 22.22 Total glycan profile 1 5 23.6 18.98 19.85 28.87 3.84 25.2 26.19 33.69 35.2 36.57 37.52 39.32 B 3 19.5 3.94 25 2 Following digestion, Neu5Gc epitopes are easily quantitated 15 1 21.7 35.26 37.56 5 16.57 3.16 27.78 16.93 19.6 22.68 24.84 27.52 33.39 39.36 C 3 25 19.7 2 15 1 21.72 24.97 Following digestion, α1-3 Galactose epitopes are easily quantitated 5 16.55 26.31 37.23 16.87 34.66 36.5 19.72 22.16 26.67 28.92 32.2 37.53 18 2 22 24 26 28 3 32 34 36 38 4 FIGURE 7: Quantitation of Neu5Gc and α1-3 Galactose epitopes. Gal Glc Man GalNAc GlcNAc Fuc NeuAc NeuGc % Neu5GC % α1-3 Galactose 7. 2.3 Conclusion Highly purified, specific exoglycosidases are valuable tools for determining the glycan profile of antibodies. Even using LC-MS, where a chromatographic peak has an exact molecular weight assignment, isoforms can make it difficult to accurately assign structures. Combinations of these enzymes can be used to highlight overall fucosylation and high mannose structures. In addition, N-glycolylneuraminic acid (Neu5Gc) and alpha-linked galactose residues, potentially immunogenic, non-human epitopes that are present in murine derived antibodies can be quantitated. The method described here has been developed to allow glycan release, labelling and exoglycosidase digestion within a work day to expedite the process of glycan sequencing. References: 1. Abes, R. et al. Pharmaceuticals 3(1) 21: 146 157. 2. Goetz, AM. et al. (211) Glycobiology (7) 949 959. One or more of these products are covered by patents, trademarks and/or copyrights owned or controlled by New England Biolabs, Inc. For more information, please email us at gbd@neb.com. The use of these products may require you to obtain additional third party intellectual property rights for certain applications. Your purchase, acceptance, and/or payment of and for NEB s products is pursuant to NEB s Terms of Sale at www.neb.com/support/terms-of-sale. NEB does not agree to and is not bound by any other terms or conditions, unless those terms and conditions have been expressly agreed to in writing by a duly authorized officer of NEB. XBridge is a trademark of Waters Corporation. LTQ and Velos is a trademark of Thermo Fisher Scientific. MICROSPIN is a trademark of Harvard Bioscience. ULTIMATE is a registered trademark of Thermo Fisher Scientific. Copyright 217, New England Biolabs, Inc.; all rights reserved. ISO 91 Registered Quality Management ISO 141 Registered Environmental Management ISO 13485 Registered Medical Devices www.neb.com New England Biolabs, Inc., 24 County Road, Ipswich, MA 1938-2723 Telephone: (978) 927-554 Toll Free: (USA Orders) 1-8-632-5227 (USA Tech) 1-8-632-7799 Fax: (978) 921-135 e-mail: info@neb.com