Identification of duck egg white N-glycoproteome and insight into the

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Identification of duck egg white N-glycoproteome and insight into the course of biological evolution Yaqi Meng, Ning Qiu, Fang Geng, Yinqiang Huo, Hao hao Sun, and Russell Keast J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.9b03059 • Publication Date (Web): 12 Aug 2019 Downloaded from pubs.acs.org on August 12, 2019

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Journal of Agricultural and Food Chemistry

Identification of duck egg white N-glycoproteome and insight into the course of biological evolution Yaqi Meng1, Ning Qiu1,2*, Fang Geng3**, Yinqiang Huo2, Haohao Sun1, Russell Keast4

1. Key Laboratory of Environment Correlative Dietology, Ministry of Education, National Research and Development Center for Egg Processing, College of Food Science and Technology, Huazhong Agricultural University, Wuhan 430070, P. R. China 2. Department of Chemical Engineering and Food Science, Hubei University of Arts and Science, Xiangyang, P. R. China 3. Meat Processing Key Laboratory of Sichuan Province, College of Pharmacy and Biological Engineering, Chengdu University, No. 2025 Chengluo Avenue, Chengdu, 610106, P. R. China 4. Centre for Advanced Sensory Science, School of Exercise and Nutrition Sciences, Deakin University, Burwood, VIC, Australia 3125 *

**

Corresponding author. Co-Corresponding author

Dr. Qiu, Fax: +86 27 87283177; e-mail: [email protected]; Tel: +86 27 87283177

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ABSTRACT

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Protein glycosylation is a ubiquitous posttranslational modification, which

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modulates protein properties, thereby influencing bioactivities within a system. Duck

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egg white (DEW) proteins exhibit diverse biological properties compared with

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chicken egg white (CEW) counterparts, which might be related to glycosylation. The

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N-glycoproteome analysis of DEW was conducted, and a total of 231 N-glycosites

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from 68 N-glycoproteins were identified. Gene Ontology analysis was used to

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elucidate the biofunctions of DEW N-glycoproteins and compared with those of

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CEW, which showed that the difference mostly participated in molecular function and

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biological process. The biological functions of DEW N-glycoproteins were

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illuminated through bioinformatic analysis for comparing with CEW orthologues,

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which showed different allergenicities and anti-bacterial abilities. These divergences

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might be initiated by specific alterations in glycosylation which enhance the

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proteolysis resistance and protein steric hindrance. These results provide new insights

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for discovering the effects of N-glycosylation on biofunctions during the divergence

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of homologue proteins.

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KEYWORDS

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Duck egg white, N-glycoproteins, Bioinformatic analysis, Bioactivities, Evolution

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INTRODUCTION Protein glycosylation is a posttranslational modification which is involved with

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modifying protein properties and bioactivities.1,

2

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complexity of egg proteins conformation, resulting in diverse functional properties.3-5

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For example, Quan et al. found that desugarization of duck egg white (DEW) could

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markedly improve the gelling properties and make the gel network more compact and

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denser.3 In addition, some protein bioactivities can be affected by the binding ability

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of carbohydrate moieties. For instance, the antivirus activity of egg ovomucin could

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be increased by the interaction of Mg2+ and the carbohydrate moieties of ovomucin.4

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Furthermore, the glycosylation of certain egg white proteins was also recognized to

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affect the egg-induced allergies.5 Alcántara et al. reported a patient with the allergy to

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DEW without chicken egg white (CEW) allergy and suggested that ovalbumin (OVA)

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might be the responsible protein.6 It was speculated that the specific egg allergenicity

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between Anseriformes and Galliformes may be due to the glycoprotein differences.

N-glycosylation increases the

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East Asia is one of the major areas for duck domestication and has a 2,000 years

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history of duck farming.7 Duck is a kind of waterfowl which often nest in the high

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humidity conditions and are omnivorous. Globally, hen eggs are the most consumed

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avian eggs, while duck eggs are specifically utilized for food processing in East Asia,

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particularly processed into salted, dried and preserved eggs.8 About 3 to 4 million

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ducks are raised each year in China, which provides an important supplement to the

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poultry industry. Besides the utilization of DEW in food processing industry, some

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DEW proteins also show diverse functions from their counterparts of CEW.9-11 For 3

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instance, DEW cystatin presents phosphorylated and glycosylated properties, both of

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which are absent in CEW.9 The gels from DEW exhibited higher cohesiveness and

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water binding property than those from CEW.10 In addition to the difference in

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proteins structure and property, the enzymatic activity of lysozyme in DEW is higher

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than its CEW counterpart.11 Geng et al. speculated that the CEW ovostatin lost some

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conversed N-glycosites by comparing with the other avian egg white ovostatins,

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which might be related to the longer domestication processes.12 Our previous

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proteomic study had performed the comparison of specific proteins between duck and

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chicken egg whites, the discrepancy in the glycosylation level between DEW and

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CEW have not been investigated.13

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Glycomics has been used to study the protein glycosylation in avian egg whites and

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its relationship with avian evolution14-16. A large-scale glycans investigation in the

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different evolutionary lineage was made through the advanced glycoblotting-based

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high-throughput glycomics, which suggested that the differences of the glycans types

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and amounts between Anseriformes and Galliformes might be related to their

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lifestyles and diet.14 The Galβ1-4Gal epitope glycans from nine avian species egg

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whites were investigated. The different expression of Galβ1-4Gal among the nine

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species may be due to the evolutionary difference, leading to different susceptibilities

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to specific infectious diseases.15 Recently, a glycoblotting study on the egg white

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proteins of four different quail species revealed various N-glycan structures.16 Besides

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the glycomics, glycoproteomics has also been used for analyzing species difference.

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The characterization and comparison of whey N-glycoproteins from bovine and 4

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human colostrum and mature milk may provide insight into the application of infant

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formulae.17 A detailed N-glycosylation analysis of the royal jelly protein between

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western and eastern honeybees revealed species-specific modifications and variations

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in immune functions.18 The N-glycoproteomic analysis of chicken egg yolk was

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conducted and provided a further understanding of embryo development, egg storage,

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and processing.19 Although glycomics analysis had been extensively used to study the

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avian egg whites, studies involving glycoproteomics are scarce. Our former omics

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analysis of CEW glycoproteins identified 71 N-glycosylation sites on 26

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glycoproteins, which gave a basic understanding of CEW glycoproteins for further

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comparison with other avians.20

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Hence, the comparative analysis of egg white N-glycoproteins between chicken and

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duck is expected to provide insight into the avian evolution.20 Previous studies have

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investigated the N-glycoproteins in some avian eggs, but little is known on the DEW

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N-glycoproteome. The DEW protein was digested by trypsin and subsequently

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deglycosylated by PNGase F in H218O. The glycosylated asparagine was transferred to

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aspartic acid with mass increased in 2.98 Da, which is detectable by LC-MS/MS. The

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glycoproteins characterization of DEW and the glycoproteome comparison to that of

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CEW are important to reveal the species diversity on bioactivities. Furthermore, this

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study will facilitate a better understanding of the glycoprotein evolution among

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different avian species.

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MATERIALS AND METHODS 5

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Sample Collection. Duck eggs laid within 24 hours were collected from the Poultry

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Research Centre farm of Huazhong Agricultural University (Wuhan, Hubei). To

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reduce variation, duck eggs were selected from a flock of 40-week-old Peking ducks

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reared in separate floor pens under standard feeding conditions. A total of nine eggs

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were randomly collected and manually separated egg white from egg yolk. Three

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sampling repeats were homogenized respectively and were further frozen at -80 ℃

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and stored at this temperature till the following analysis.

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Protein Extraction. The frozen DEW (1 mL) lyophilized powder was grinded and

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sonicated (150 W, 30 s each time) in four volumes of lysis buffer (10 mmol/L

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dithiothreitol, 1% protease inhibitor cocktail, and 1% phosphorylase inhibitor),

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followed by centrifugation with isometric Tris-saturated phenol at 5,500 × g at 4 ℃

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for 10 min. Then, the supernatant was mixed with four volumes of ammonium

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acetate/methanol (0.1 mol/L) and incubated overnight. After that, the remaining

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precipitate was washed with methanol and acetone respectively. The protein was

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redissolved in 8 mol/L urea and then the protein concentration was determined by

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using BCA kit according to the manufacturer’s instructions.21

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Trypsin Digestion. The method was based on our previous protocol.20 For digestion,

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the DEW protein solution was treated with 5 mmol/L dithiothreitol for 30 min at 56 ℃

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and then with 11 mmol/L iodoacetamide for 15 min at room temperature in the dark.

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The alkylated samples were diluted by adding 100 mmol/L NH4HCO3 to make the

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urea concentration less than 2 mol/L. Finally, trypsin (Promega) was added (trypsin:

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protein, 1:50, w/w) for the first digestion overnight and (trypsin: protein, 1:100, w/w)

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for a second 4 h-digestion respectively.

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HPLC Fractionation. The tryptic peptides were fractionated by high pH

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reverse-phase HPLC using Thermo Betasil C18 column (5 μm particles, 10 mm inner 6

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diameter, 250 mm length). The peptides were separated firstly with a gradient of 8%

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to 32% acetonitrile (pH 9.0) over 60 min into 60 fractions (Figure S2A). Then, the

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peptides were combined into four fractions and dried by vacuum centrifuging (Figure

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S2B).

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Glycopeptides Enrichment. To enrich the DEW glycosylation peptides, tryptic

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peptides were dissolved in the enrichment buffer (40 µL, 80% acetonitrile and 1%

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trifluoroacetic acid) and then transferred to the hydrophilic interaction liquid

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chromatography microcolumn (HILIC, SeQuant, Southborough, MA, USA) with

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centrifuge at 4000 × g for 15 min. After that, the enrichment buffer was used to wash

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3 times on the hydrophilic microcolumn of HILIC.22 After using 10% acetonitrile to

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elute the glycopeptides, the elute was collected and lyophilized. Then, the

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glycopeptides were redissolved in the 50 mmol/L ammonium bicarbonate buffer (50

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µL), added with 2 µL of PNGase F (Roche, 11365185001, Mannheim, Germany) and

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incubated at 37°C overnight. For LC-MS/MS analysis, the resulting peptides were

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desalted with C18 ZipTips (Millipore, Billerica, MA, USA) according to the

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manufacturer’s instructions and the enriched DEW glycopeptides were lyophilized.

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LC-MS/MS Analysis. The separating and analysis of the glycopeptides were carried

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out by UPLC-NSI-MS/MS with an ESAY-nLC 1000 UPLC system (Thermo Fisher

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Scientific, Bremen, Germany). The tryptic glycopeptides were dissolved in 0.1%

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formic acid and 2% acetonitrile (solvent A). The gradient of solvent B (0.1% formic

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acid in 98% acetonitrile) was comprised an increase from 5% to 20% over 26 min,

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20% to 32% in 8 min, then climbing to 80% in 3 min and holding at 80% for 3 min.

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The constant flow rate was all at 700 nL/min. Then, the peptides were subjected to

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NSI source followed by tandem mass spectrometry in the Orbitrap FusionTM. The

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electrospray voltage applied was 2.2 kV. The first-order m/z scan range was 350 to 7

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1550, and intact peptides were detected at a resolution of 60,000 in the Orbitrap.

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Then, the peptides were detected in the Orbitrap at a resolution of 15,000. A

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data-dependent procedure that alternated between one MS scan followed by 20

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MS/MS scans with 15 s dynamic exclusion. Automatic gain control was set at 5E4.

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Database Search. The secondary mass spectrometry data was retrieved using

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Maxquant search engine (v1.5.2.8) and compared against the NCBI databases

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(organism: Anas platyrhynchos). As the cleavage enzyme, trypsin was allowed up to 2

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missing cleavages. The first search and the main search of mass tolerances of the

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precursor ions were set as 20 ppm and 5 ppm respectively. Subsequent mass tolerance

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was set to 0.02 Da for the fragment ions. Carbamidomethyl on Cys was specified as

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fixed modification, oxidation on Met and deamidation with 18O on Asn were specified

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as variable modifications. For identification, the false discovery of the peptide and site

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levels rate was specified as 1%.

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Bioinformatics Analysis. Gene Ontology (GO) analysis of the identified DEW

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glycoproteins was derived using the database for annotation. The pathways were

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identified according to the Kyoto Encyclopedia of Genes and Genomes database. All

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identified glycoprotein name identifiers were searched against the STRING database

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version 10.5 for protein-protein interactions. Protein-protein interaction network of

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the glycoproteins was also established with the use of Cytoscape software. The

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functional description of ovotransferrin (OTF) was annotated against the database of

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InterProScan (http://www.ebi.ac.uk/interpro/). The locations of the N-glycosylation

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sites of OTF were visualized and presented by Illustrator for Biological Sequences 1.0

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program.23 The data of CEW N-glycoproteins from our previous study were used for

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bioinformatic analysis and comparison with that of DEW.20

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RESULTS AND DISCUSSION

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Mapping of the N-glycosites in DEW proteins

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To study the N-glycoproteins in DEW samples, the tryptic DEW peptides were

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treated with PNGase F to remove the N-glycans for subsequent LC-MS/MS analysis.

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Based on the shift in protein molecular mass, a total of 68 N-glycoproteins carrying

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231 N-glycosites were identified (Table S1). All the peptide ions had a mass tolerance

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less than 5 ppm, indicating high precision (Figure 1A). The distribution of DEW

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N-glycosites was shown in Figure 1B. Of these N-glycoproteins, 37 glycoproteins

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from DEW contained a single glycosite, which was more than that of CEW (12

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glycoproteins).20 The number of glycosites per DEW protein varied from 1 to 42. The

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highest number of N-glycosites (42 sites) was detected in mucin-5B (Table S1), while

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only 15 N-glycosites were identified in CEW mucin-5B.20 Most of the N-glycosites

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identified in DEW were matched with the N-X-[T/S] (X≠proline/p) motif, and the

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proportion of the N-X-T motif (36%) was higher than that of N-X-S (26%) (Figure

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1C). In addition to the conserved N-X-[T/S] motif, N-X-C was shown to present at a

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high frequency in this study, and the frequency of the less detected motifs was higher

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in DEW (32%) than that in CEW (9%).20

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Bioinformatic analysis of DEW N-glycoproteins

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The detected N-glycoproteins of DEW were conducted with GO analysis. As

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shown in Figure 2, all mapped N-glycoproteins were classified in accordance with

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their biological processes, cellular component, and molecular function at level 2.

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Multiple N-glycoproteins coevolved with the rise of extracellular processes,

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potentially signifying significant role in organism development, embryo growth, and

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organ formation.24 In the present study, the distribution of mapped glycoproteins was

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mainly clustered in the extracellular region (Figure 2A), which was in accordance 9

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with the coevolution theory. In terms of molecular function (Figure 2B), the largest

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proportion of identified N-glycoproteins in DEW was involved in binding

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(GO:0005488), followed by catalytic activity (GO:0003824), which was performed by

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a variety of enzymes. In this study, various glycosylated hydrolases, especially

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glycosylases, were identified in DEW (Table S1). Besides, the β-galactosidase in

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DEW were involved in some pathways as shown in Figure 3. It was shown that there

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was a greater variety of hydrolases found in DEW than in CEW, suggesting certain

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unique functions for waterfowl.25 It was reported that the N-linked glycans were

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required for the enzyme activity of β-glucosidase,26 which was related to the

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carbohydrate metabolic process. Therefore, the glycans of DEW glycosidases might

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play an important role in stabilizing their enzymatic activities to release sugars for

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meeting the energetic fuel during the embryo development.

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The N-glycoproteins of CEW were identified in our previous study.20 Here, the

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comparative GO analysis between DEW and CEW was performed. The distribution of

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cellular component in DEW and CEW N-glycoproteins was similar (Figure 2A and

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Figure S1A). A higher percentage (58%) of CEW N-glycoproteins were clustered into

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the molecular function of binding compared with DEW (40%), while more DEW

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N-glycoproteins (35%) were enriched in catalytic activity compared with CEW (11%)

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(Figure 2B and Figure S1B). Major N-glycoproteins in DEW were associated with the

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metabolic process and single-organism process while CEW glycoproteins were

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mainly distributed in biological regulation (Figure 2C and Figure S1C). A larger

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number of metabolic process-related glycoproteins were found in DEW (36%) than in

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CEW (8%). It was reported that the enzymatic efficiency could be modulated by the

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glycoprotein N-glycans26, and the alteration of enzymatic efficiency might be related

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to the higher energy demand for duck. 10

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The protein-protein interaction network was carried out on the interaction of

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N-glycoproteins in DEW (Figure 4A) and CEW (Figure 4B). The edges and nodes

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represent the interaction of glycoproteins. The DEW glycoprotein interaction network

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contained 21 predicted interactions involving 18 N-glycoproteins. Among these

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interacted glycoproteins, some bore enzymatic activities, including A2M, PLG, OM,

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and A2ML1. The SPINK7 in CEW and SERPINB14 in DEW were both represented

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as ovalbumin, but with 1 and 4 N-glycosite(s) identified respectively. The predicted

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proteins interacted with DEW and CEW ovalbumin were also different. Whether and

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how the diverse glycosylation affects the interaction among these glycoproteins

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requires further study.

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Characterization of the N-glycoproteome in DEW

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Through the comparison of DEW and CEW N-glycoproteoms (Figure 1D), fifteen

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N-glycoproteins were conserved in these two species. Based on the GO analysis, these

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conserved N-glycoproteins were involved in protein binding, localization and

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regulating enzyme activity. There were 53 unique glycoproteins identified in DEW,

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such as legumain, carboxypeptidase D precursor, and deleted in malignant brain

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tumors 1 protein-like (DMBT1PL), which might be involved in the species-specific

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properties or bioactivities. For instance, the glycosylation of immature legumain was

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important on the localization and processing to its active form.27 And DMBT1PL, as a

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specific glycoprotein in DEW, was presented with nine SRCR domains where the

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glycans were identified to affect the innate immunity based on the ligand binding

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properties.28 The glycosylation domains adjacent to SRCR domains harbor an

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essential role in binding virus.29 Therefore, the carbohydrate moieties on DMBT1PL

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might enhance the DEW antibacterial activity.

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Antibacterial-related N-glycoproteins in DEW 11

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Considering that the duck eggshell from commercial hatcheries is mainly

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contaminated with Gram-positive cocci, it is probable that the cavity-nesting

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environment may lead to more potent egg white antimicrobial activities to defend the

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Gram-positive bacteria attacks.30,

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DEW, which could inhibit most gram-positive bacteria by hydrolyzing the

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peptidoglycan cell wall.32 In addition, some proteins like OTF and riboflavin-binding

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protein (RFBP) inhibit the bacteria by competitive binding with the bacteria-required

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elements. For example, RFBP can eliminate free riboflavin in egg white and the

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riboflavin binding activity may be decreased by deglycosylation.33

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Lysozyme is a major antimicrobial protein in

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In this study, nine N-glycosites were identified in DEW OTF but only three

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glycosites were found in CEW.20 A comparative study suggested that the various of

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OTF N-glycoforms between chicken and pheasant might influence the biofunctions

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by changing the primary structure of OTF.34 According to the high sequence identity

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between DEW and CEW OTF, the higher amount of N-glycosites in DEW OTF might

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be the main reason for its variation in antimicrobial activity. Ghanbari et al. reported

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that the glycans on the C-lobe of OTF might affect the layout of iron binding site

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residue and subsequently affect the transferrin function.35 As shown in Fig 5, most of

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the N-glycosites were concentrated on the Transferrin domain (PF00405) which

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contained active sites showing ferric iron binding activity. Consequently, it could be

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el suggested that these concentrated N-glycans may influence the dynamics of OTF

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structures and subsequently affect the antibacterial activity.

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In DEW lysozyme, a total of 4 N-glycans were detected. All of the N-glycosites

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were localized at the noncanonical motifs (NXC, NXR, NXD, NXE), which was

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similar to those of CEW lysozyme.36 It was suggested that the nesting under humid

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conditions might enhance the bacterial contamination and waterfowl might evolve 12

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higher antimicrobial activity.30,31 Additionally, the conjugation of polysaccharide and

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lysozyme could strengthen the protein surface activity to attack the bacteria which

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contained hydrophobic material on the envelop, while the native lysozyme without

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polysaccharide failed to lyse gram-negative bacteria.37 Thus, the different antibacterial

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spectrum or activity between CEW and DEW may rely on the lysozyme carbohydrate

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moieties, however this requires further study.

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In this study, 42 N-glycosites were detected in DEW Mucin-5B, which is a subunit

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of ovomucin.38 Mucin-6, another submit of ovomucin, was identified with only one

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N-glycosite. It was reported that the glycopeptides derived from CEW ovomucin

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could prevent bacteria adhering to porcine erythrocytes.39 Other studies demonstrated

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that the N-glycans also play a vital role in protein dimerization and polymerization,

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which prevent egg white thinning during storage.40,41 Therefore, the relative higher

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viscosity in DEW may be caused by the abundant N-glycosites of duck mucin-5B,

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which can also enhance the antibacterial activity by limiting the bacteria movement.

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Allergy-related N-glycoproteins in DEW

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Among the 13 glycosites identified in DEW ovomucoid (OM), 5 of them (N7, N51,

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N73, N156, and N173) with motif N-X-[S/T] (X≠P/proline) were canonical sites

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while 8 were noncanonical sites (N11, N37, N45, N76, N102, N110, N164, and

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N167). There was a controversy about whether the carbohydrate moieties are the

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active fragment of antigenicity.42-44 Zhang et al. reported that the OM glycans had an

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inhibitory effect on the protein binding properties to IgG and IgE,43 and another study

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found that the N-linked glycan, especially the mannose chain on the OM domain III,

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was shown to be related with the suppression of allergic response.44 Moreover, the

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OM domain III was more related to allergenic than domain I and II.43 Many

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N-glycosites were identified in the third domain of DEW OM, which might reduce the 13

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allergenicity. On the other hand, it was reported that the carbohydrate moieties were

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responsible for an increased resistance to proteolysis and resulted in its allergenic

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potency.45 It was reported that two specific IgE recognition epitopes in CEW OM

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(DCSRFPNATDKE and FNPVCGTDGVTYDN) and the N-glycosites were both

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identified in our former work.20,46 Here, the similar peptides (DCSRFPNTTNEE and

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FSPVCGTDGYTYDN) were glycosylated in DEW, which might be related to its

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allergenicity. Therefore, it may be speculated that the glycans on DEW OM can not

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only prevent the IgE recognition epitopes from being degraded, but also affect the

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protein steric hindrance. And the discrepancy of the glycosylated OM between duck

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and chicken egg whites may contribute to their specific allergenicity.6,20

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Two independent N-glycosites and a pair of adjacent-glycosites were identified in

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duck RFBP (Table S1). It was reported that the secondary and tertiary structure of

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RFBP could be affected by its carbohydrate moieties.47 Besides, a study on the effects

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of the adjacent serine O-glycosylation showed that the clustered carbohydrates shifted

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the conformational equilibrium as well as the target binding sites.48 Moreover, the

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carbohydrate moieties, especially the sialic acid, were essential for protein transport

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and biological functions.33 Thus, it could be postulated that the adjacent-glycosites on

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duck RFBP might affect the IgE binding activity by changing the protein structure.

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Lysozyme is also recognized to be associated with allergies. The specific

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glycosylation of hen egg lysozyme could result in the steric hindrance on protein

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interfacial region and subsequently, reduce the antigenicity dramatically.49 Moreover,

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OVA, as one of the most studied allergenic proteins, was identified with 4

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N-glycosites in DEW. It has been demonstrated that the deglycosylation of OVA

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N-terminal glycan decreased the allergenicity and antigenicity.5 It was reported that

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the glycation by Maillard reaction could influence the allergenicity of ovalbumin, 14

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which could contribute to the alteration of the resistance to digestive enzymes.50 Thus,

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the difference of OVA carbohydrate moieties between DEW and CEW might also

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contribute to the alteration of species-specific allergenicity, which demands further

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investigation.

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To conclude, the N-glycoproteome of DEW was investigated and compared to

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CEW with bioinformatics analysis in this study. In total, 231 N-glycosites on 68

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glycoproteins were identified in DEW. According to the restriction of trypsin

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digestion strategy, however, some N-glycosites might still be undetected, which needs

318

further analysis by using combination of different enzymes. Meanwhile, the

319

identification of N-glycosite information might also be interfered by the simultaneous

320

existence of O-glycans. GO functional annotations of the N-glycoproteins in DEW

321

and CEW revealed their variations in biological functions. The comparison of

322

glycosites between CEW and DEW N-glycoproteins elicited difference in the

323

allergenicity as well as antibacterial activity. The divergence of these glycoprotein

324

homologues was suggested to be evolved with the adaption to various environmental

325

stresses, such as the need for defending against infections. Meanwhile, the

326

N-glycosites variations between DEW and CEW proteins may be related to the

327

poultry domestication process, which provided new insight into the poultry

328

evolutionary history.

329 330

Abbreviations Used

331

DEW, duck egg white; CEW, chicken egg white; HILIC, Hydrophilic interaction

332

liquid chromatography; GO, Gene Ontology; DMBT1PL, Deleted in malignant brain

333

tumors 1; OTF, Ovotransferrin; RFBP, Riboflavin-binding protein; OM, Ovomucoid;

334

OVA, Ovalbumin. 15

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335

Funding

336

This work was financially supported by the Chinese National Natural Science Funds

337

(Grant No. 31772043), Fundamental Research Funds for the Central Universities

338

(Program No. 2662018JC021 & Project No. 2019BC008), Co-construction Research

339

and Development Project of Hubei University of Arts & Science (Project No.

340

F51805).

341

Conflicts of interest

342

The authors declare no competing financial interests.

343

Supporting Information

344

The details of DEW N-glycopeptides resulting from a database search of LC-MS/MS

345

data are shown in Supporting Table (Table S1); Gene Ontology analysis (level 2) of

346

the N-glycoproteins in CEW are shown in Supporting Figure (Figure S1, the list of

347

CEW N-glycoproteins was from the previous work20); The HPLC separation data and

348

the basis of components classifications are shown in the Supporting file (Figure S2, A.

349

The HPLC separation chromatogram data of trypsin digested protein mixtures. B.

350

Illustration of the 60 components separated into 4 fractions); The chromatograms of

351

the LC-MS/MS analysis of trypsin digests DEW glycoproteins are shown in the

352

Supporting file (Supporting Figures).

353

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Figure Captions

503

Figure 1. Characteristics of the identified duck N-glycoproteins. A. Mass error

504

distribution of identified DEW N-glycopeptides. B. Distribution of single and

505

multiple DEW N-glycoproteins. C. Distribution of recognized sequence motifs in

506

DEW N-glycoproteins. D. Venn diagrams of identified N-glycoproteins between duck

507

and chicken egg whites (the list of CEW N-glycoproteins was from the previous

508

work20).

509 510

Figure 2. Gene Ontology (GO) analysis (level 2) of the N-glycoproteins in DEW.

511 512

Figure 3. Duck egg white glycoproteins involved in the glycan degradation KEGG

513

pathway. Red lines denote the severable glycosyl bonds.

514 515

Figure 4. Protein-protein interaction network analysis of the N-glycoproteins in duck

516

egg white (A) and chicken egg white (B, the list of CEW N-glycoproteins was from

517

the previous work20). Disconnected nodes are hidden.

518 519

Figure 5. Locations of the identified N-glycosites on DEW ovotransferrin.

520 521

Figure S1. Gene Ontology analysis (level 2) of the N-glycoproteins in CEW (the list

522

of CEW N-glycoproteins was from the previous work20).

523 24

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Figure S2. The HPLC separation data and the basis of components classifications

525

(Figure S2, A. The HPLC separation chromatogram data of trypsin digested protein

526

mixtures. B. Illustration of the 60 components separated into 4 fractions).

527 528

Supporting Figures. The chromatograms of the LC-MS/MS analysis of trypsin

529

digests DEW glycoproteins

530 531

Table S1. The details of DEW N-glycopeptides resulting from a database search of

532

LC-MS/MS data.

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533

Figure graphics

534 535

Figure 1. Characteristics of the identified duck N-glycoproteins. A. Mass error

536

distribution of identified DEW N-glycopeptides. B. Distribution of single and

537

multiple DEW N-glycoproteins. C. Distribution of recognized sequence motifs in

538

DEW N-glycoproteins. D. Venn diagrams of identified N-glycoproteins between duck

539

and chicken egg whites (the list of CEW N-glycoproteins was from the previous

540

work20).

541

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542 543

Figure 2. Gene Ontology (GO) analysis (level 2) of the N-glycoproteins in DEW.

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544 545

Figure 3. Duck egg white glycoproteins involved in the glycan degradation KEGG

546

pathway. Red lines denote the severable glycosyl bonds.

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547 548

Figure 4. Protein-protein interaction network analysis of the N-glycoproteins in duck

549

egg white (A) and chicken egg white (B, the list of CEW N-glycoproteins was from

550

the previous work20). Disconnected nodes are hidden.

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551 552

Figure 5. Locations of the identified N-glycosites on DEW ovotransferrin.

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Journal of Agricultural and Food Chemistry

Graphic for table of contents

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Figure 1. Characteristics of the identified duck N-glycoproteins. A. Mass error distribution of identified DEW N-glycopeptides. B. Distribution of single and multiple DEW N-glycoproteins. C. Distribution of recognized sequence motifs in DEW N-glycoproteins. D. Venn diagrams of identified N-glycoproteins between duck and chicken egg whites (the list of CEW N-glycoproteins was from the previous work22). 312x245mm (300 x 300 DPI)

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Figure 2. Gene Ontology (GO) analysis (level 2) of the N-glycoproteins in DEW. 498x193mm (300 x 300 DPI)

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Figure 3. Duck egg white glycoproteins involved in the glycan degradation KEGG pathway. Red lines denote the severable glycosyl bonds. 546x347mm (300 x 300 DPI)

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Figure 4. Protein-protein interaction network analysis of the N-glycoproteins in duck egg white (A) and chicken egg white (B, the list of CEW N-glycoproteins was from the previous work22). Disconnected nodes are hidden. 501x216mm (300 x 300 DPI)

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Figure 5. Locations of the identified N-glycosites on DEW ovotransferrin. 49x23mm (300 x 300 DPI)

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