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- E-ISSN 2093-8950
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- P-ISSN2233-4203
- E-ISSN2093-8950
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MS-Based Technologies for the Study of Site-Specific Glycosylation
Mass Spectrometry Letters / Mass Spectrometry Letters, (P)2233-4203; (E)2093-8950
2017, v.8 no.4, pp.69-78
https://doi.org/10.5478/MSL.2017.8.4.69
(Chungnam National University, GLYCAN Co., Ltd.,)
(Chungnam National University)
(Chungnam National University)
(Chungnam National University)
(Chungnam National University)
(Chungnam National University)
(Chungnam National University)
(Chungnam National University)
(Chungnam National University)
Kim,
U., Oh,
M. J., Lee,
J., Hwang,
H. Y., &
An,
H.
J.
(2017). MS-Based Technologies for the Study of Site-Specific Glycosylation. Mass Spectrometry Letters, 8(4), 69-78, https://doi.org/10.5478/MSL.2017.8.4.69
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Abstract
Glycosylation, which is one of the most common post-translation modification (PTMs) of proteins, plays a variety of crucial roles in many cellular events and biotherapeutics. Recent advances have led to the development of various analytical methods employing a mass spectrometry for glycomic and glycoproteomic study. However, site-specific glycosylation analysis is still a relatively new area with high potential for technologies and method development. This review will cover current MSbased workflows and technologies for site-specific mapping of glycosylation ranging from glycopeptide preparation to MS analysis. Bioinformatic tools for comprehensive analysis of glycoprotein with high-throughput manner will be also included.
- keywords
- Glycosylation, Glycopeptide, Mass Spectrometry, Site-specific mapping, Bioinformatics
Reference
1
Apweiler, R. (1999). . BBA-Gen. Subjects, 1473, 4-.
2
James, W. Dennis. (1999). . BioEssays, 21, 421-.
3
Moremen, K. W. (2012). . Nat. Rev. Mol. Cell Biol, 13, 448-.
4
Dwek, R. A. (2002). . Nat. Rev. Drug Discov, 1, 65-.
5
Jefferis, R. (2009). . Trends Pharmacol. Sci, 30, 356-.
6
Li, H. (2009). . Curr. Opin. Biotechnol, 20, 678-.
7
Lingg, N. (2012). . Biotechnol. J, 7, 1462-.
8
Mariño, K. (2010). . Nat. Chem. Biol, 6, 713-.
9
Wuhrer, M. (2005). . J. Chromatogr. B, 825, 124-.
10
Kolarich, D. (2012). . Curr. Opin. Chem. Biol, 16, 214-.
11
Park, Y. (2005). . Mass Spectrom. Rev, 24, 232-.
12
An, H. J. (2009). . Curr. Opin. Chem. Biol, 13, 421-.
13
안현주. (2015). MS Platform for Erythropoietin Glycome Characterization. Mass Spectrometry Letters, 6(3), 53-58. http://dx.doi.org/10.5478/MSL.2015.6.3.53.
14
Wuhrer, M. (2007). . J. Chromatogr. B, 849, 115-.
15
Klampfl, C. W. (2006). . Electrophoresis, 27, 3-.
16
Zamfir, A. (2001). . Electrophoresis, 22, 2448-.
17
Harazono, A. (2008). . J. Chromatogr. B, 869, 20-.
18
Nilsson, J. (2016). . Glycoconj. J, 33, 261-.
19
Plematl, A. (2005). . Proteomics, 5, 4025-.
20
Tajiri, M. (2005). . Glycobiology, 15, 1332-.
21
Zauner, G. (2010). . J. Sep. Sci, 33, 903-.
22
Singh, C. (2012). . J. Proteome Res, 11, 4517-.
23
Pai, P. -J. (2016). . Anal. Chim. Acta, 934, 152-.
24
Zhang, Y. (2018). . J. Proteomics, 170, 14-.
25
Scott, N. E. (2011). . Mol Cell Proteomics, 10, -.
26
Wang, D. (2011). . Anal. Chem, 83, 2029-.
27
Olsen, J. V. (2007). . Nat. Methods, 4, 709-.
28
Thaysen-Andersen, M. (2014). . BBA-Proteins and Proteom, , 1844-.
29
Kolarich, D. (2012). . Nat. Protoc, 7, 1285-.
30
Leymarie. N. (2013). . Mol. Cell. Proteomics, 12, 2935-.
31
Faid, V. (2014). . Proteomics, 14, 2460-.
32
Jiang, J. (2014). . Anal. Bioanal. Chem, 406, 6265-.
33
Ohta, M. (2002). . Biologicals, 30, 235-.
34
Hua, S. (2012). . Anal. Bioanal. Chem, 403, 1291-.
35
Hua, S. (2013). . J. Proteome Res, 12, 4414-.
36
Plomp, R. (2014). . J. Proteome Res, 13, 536-.
37
Alvarez-Manilla, G. (2006). . J. Proteome Res, 5, 701-.
38
Joenvaara, S. (2008). . Glycobiology, 18, 339-.
39
Hemstrom, P. (2006). . J. Sep. Sci, 29, 1784-.
40
Groleau, P. E. (2008). . J. Mass Spectrom, 43, 924-.
41
Huddleston, M. J. (1993). . Anal. Chem, 65, 877-.
42
Cointe, D. (2000). . Glycobiology, 10, 511-.
43
Thaysen-Andersen, M. (2011). . Electrophoresis, 32, 3536-.
44
Dam, S. (2013). . J. Proteome Res, 12, 3383-.
45
Thaysen-Andersen, M. (2014). . BBA-Proteins Proteom, 1844, 1437-.
46
Hua, S. (2015). . J. TrAC- Trends Anal. Chem, 68, 18-.
47
Sun, B. (2007). . Mol. Cell. Proteomics, 6, 141-.
48
Stadlmann, J. (2017). . Nature, 549, 538-.
49
Parker, B. L. (2013). . J. Proteome Res, 12, 5791-.
50
Halim, A. (2012). . Mol. Cell. Proteomics, 11, 1-.
51
Halim, A. (2013). . J. Proteome Res, 12, 573-.
52
Jensen, L. J. (2009). . Nucleic Acids Res, 37, D412-.
53
Ueda, K. (2013). . Proteomics Clin. Appl, 7, 607-.
54
Tian, Y. (2010). . Proteomics Clin. Appl, 4, 124-.
55
Cancilla, M. T. (1999). . Anal. Chem, 71, 3206-.
56
Hua, S. (2013). . J. Proteome Res, 12, 4414-.
57
Mayampurath, A. (2014). . Anal. Chem, 86, 453-.
58
Anonsen, J. H. (2012). . J. Proteome Res, 11, 5781-.
59
Yin, X. (2013). . Mol. Cell. Proteomics, 12, 956-.
60
Trinidad, J. C. (2013). . Mol. Cell. Proteomics, 12, 3474-.
61
Thannhauser, T. W. (2013). . Electrophoresis, 34, 2417-.
62
Nilsson, J. (2009). . Nat. Methods, 6, 809-.
63
Uematsu, R. (2005). . Mol. Cell. Proteomics, 4, 1977-.
64
Nwosu, C. C. (2011). . J. Proteome Res, 10, 2612-.
65
Hong, Q. (2015). . J. Proteome Res, 14, 5179-.
66
Jebanathirajah, J. (2003). . J. Am. Soc. Mass. Spectrom, 14, 777-.
67
Hu, H. (2016). . Glycoconj. J, 33, 285-.
68
Bykova, N. V. (2006). . Anal. Chem, 78, 1093-.
69
Syka, J. E. P. (2004). . Proc. Natl. Acad. Sci. U. S. A, 101, 9528-.
70
Wiesner, J. (2008). . Proteomics, 8, 4466-.
71
Kim, M. -S. (2012). . Proteomics, 12, 530-.
72
Håkansson, K. (2001). . Anal. Chem, 73, 4530-.
73
Leymarie, N. (2012). . Anal. Chem, 84, 3040-.
74
Yu, Q. (2017). . J. Am. Soc. Mass. Spectrom, 28, 1751-.
75
Ko, B. J. (2015). . Int. J. Mass spectrom, 377, 385-.
76
Aboufazeli, F. (2015). . J. Am. Soc. Mass Spectrom, 26, 587-.
77
An, H. J. (2011). . Mass Spectrom. Rev, 30, 560-.
78
Oh, M. J. (2016). . J. Bioanalysis, 8, 711-.
79
Ceroni, A. (2008). . J. Proteome Res, 7, 1650-.
80
Lohmann, K. K. (2003). . Proteomics, 3, 2028-.
81
Li, J. (2010). Functional Glycomics: Methods and Protocols:Humana Press.
82
Catherine A. Cooper. (2001). . Proteomics, 1, 340-.
83
Wu, Y. (2010). . Rapid Commun. Mass Spectrom, 24, 965-.
84
Lee, L. Y. (2016). . J. Proteome Res, 15, 3904-.
85
Strum, J. S. (2013). . Anal. Chem, 85, 5666-.
86
Chandler, K. B. (2013). . J. Proteome Res, 12, 3652-.
87
Park, G. W. (2016). . Sci. Rep, 6, 2117-.
88
Lih, T. M. (2016). . Nucleic Acids Res, 44, w575-.
89
Lynn, K. S. (2015). . Anal. Chem, 87, 2466-.
90
Liu, M. Q. (2017). . Nat. Commun, 8, 438-.
- Submission Date
- 2017-11-17
- Revised Date
- 2017-12-18
- Accepted Date
- 2017-12-18
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