Applications of chromatography in glycomics

doi:10.3724/SP.J.1123.2023.12003

Abstract

Abstract:

Glycomics, an emerging “omics” technology that was developed after genomics and proteomics, is a discipline that studies the composition, structure, and functions of glycomes in cells, tissues, and organisms. Glycomics plays key roles in understanding the laws of major life activities, disease prevention and treatment, and drug quality control and development. At present, the structural analysis of glycans relies mainly on mass spectrometry. However, glycans have low abundance in biological samples. In addition, factors such as variable monosaccharide compositions, differences in glycosidic bond positions and modes, diverse branching structures, contribute to the complexity of the compositions and structures of glycans, posing great challenges to glycomics research. Liquid chromatography can effectively remove matrix interferences and enhance glycan separation to improve the mass spectrometric response of glycans. Thus, liquid chromatography and liquid chromatography coupled with mass spectrometry are important technical tools that have been actively applied to solve these problems; these technologies play indispensable roles in glycomics research. Different studies have highlighted similarities and differences in the applications of various types of liquid chromatography, which also reflects the versatility and flexibility of this technology.

In this review, we first discuss the enrichment methods for glycans and their applications in glycomics research from the perspective of chromatographic separation mechanisms. We then compare the advantages and disadvantages of these methods. Some glycan-enrichment modes include affinity, hydrophilic interactions, size exclusion, and porous graphitized carbon adsorption. A number of newly developed materials exhibit excellent glycan-enrichment ability. We enumerate the separation mechanisms of reversed-phase high performance liquid chromatography (RP-HPLC), high performance anion-exchange chromatography (HPAEC), hydrophilic interaction chromatography (HILIC), and porous graphitic carbon (PGC) chromatography in the separation and analysis of glycans, and describe the applications of these methods in the separation of glycans, glycoconjugates, and glyco-derivatives. Among these methods, HILIC and PGC chromatography are the most widely used, whereas HPAEC and RP-HPLC are less commonly used. The HILIC and RP-HPLC modes are often used for the separation of derived glycans. The ionization efficiency and detectability of glycans are significantly improved after derivatization. However, the derivatization process is relatively cumbersome, and byproducts inevitably affect the accuracy and completeness of the detection results. HPAEC and PGC chromatography exhibit good separation effects on nonderivative glycans, but issues related to the detection integrity of low-abundance glycans owing to their poor detection effect continue to persist. Therefore, the appropriate analytical method for a specific sample or target analyte or mutual verification must be selected.

Finally, we highlight the research progress in various chromatographic methods coupled with mass spectrometry for glycomics analysis. Significant progress has been made in glycomics research in recent years owing to advancements in the development of chromatographic separation techniques. However, several significant challenges remain. As the development of novel separation materials and methods continues, chromatographic techniques may be expected to play a critical role in future glycomics research.

Key words: liquid chromatography (LC), glycomics, glycan enrichment, glycan separation

CLC Number:

O658

ZHENG Yi, CAO Cuiyan, GUO Zhimou, YAN Jingyu, LIANG Xinmiao. Applications of chromatography in glycomics[J]. Chinese Journal of Chromatography, 2024, 42(7): 646-657.

Figures/Tables 5

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Enrichment method	Stationary phase or column	Applications	Eluent	Advantages and limitations	Ref.
AFC	Sambucus nigra agglutinin agarose	core fucosylation and the sialic acid linkage of prostate-specific anti- gens, N-glycans of serum samples	0.5 mol/L lactose in 1%BSA	good selectivity and high efficiency, but lack of general applicability	[21]
HILIC-SPE	SeQuant ZIC-HILIC	glycopeptides from human serum	1% TFA aqueous solution	universality, but	[25]
	cotton wool pads	IgG Fc N-glycans and N-glycopeptides	water	unsatisfactory repeatability	[27]
	histidine-bonded silica	N-glycopeptides from BSA/fetuin mixture digests, human serum tryptic digests	40% ACN/5 mmol/L NH₄HCO₃ (pH 8.2)		[29]
HILIC	TSKgel Amide 80	2-AA-labeled N-glycans of human plasma	80% ACN, 20% 50 mmol/L ammonium formate (pH 4.4)	universality and rapidity, but low selectivity owing	[31]
	Ultimate HILIC amphion column	N-glycopeptides of horseradish per- oxidase, ovalbumin, human holo- transferrin, and human serum	A: 0.1%TFA; B: 0.1%TFA in ACN; 0-20 min, 80%B; 21-30 min, 2%B; 31-38 min, 80%B	to nonspecific adsorption	[33]
	Click Maltose	N-glycopeptides of IgG, BSA and human serum with and without pancreatic tumors	A: 0.1%TFA; B: 0.1%TFA/98% ACN; 0-11 min, 82%B; 11-13 min, 30%B; 13-15 min, 0B		[35]
SEC	oxidized meso- porous carbon ma- terial (O-CMK-3)	N-glycans of hen ovalbumin, BSA, human serum from healthy volun- teers and patients with liver cancer	50% ACN solution	rarely applied, SEC only used as an auxiliary of carbon materials	[36]
PGC-SPE	PGC cartridges	human milk oligosaccharides	20% ACN in water and 40% ACN in 0.05%TFA aqueous solution	universality and high enrichment scale, but	[39]
	PGC cartridges	N-glycans of recombinant human α-galactosidase	steps: 1) 20% ACN in H₂O; 2) 10% ACN in H₂O with 0.05% TFA; 3) 40% ACN in H₂O with 0.05%TFA	unsatisfactory stability and repeatability	[40]
Metal oxides- SPE	combined TiO₂/ZrO₂ resin	N-glycans with mono- or diphospho-esters of recombinant β-glucuronidase	digested with calf intestinal alkaline phosphatase on resin in 50 mmol/L Tris-HCl, pH 9.3, 1 mmol/L MgCl₂, 0.1 mmol/L ZnCl₂, and 1 mmol/L spermidine at 37 ℃ overnight	lack of general applicability	[53]

Enrichment method	Stationary phase or column	Applications	Eluent	Advantages and limitations	Ref.
AFC	Sambucus nigra agglutinin agarose	core fucosylation and the sialic acid linkage of prostate-specific anti- gens, N-glycans of serum samples	0.5 mol/L lactose in 1%BSA	good selectivity and high efficiency, but lack of general applicability	[21]
HILIC-SPE	SeQuant ZIC-HILIC	glycopeptides from human serum	1% TFA aqueous solution	universality, but	[25]
	cotton wool pads	IgG Fc N-glycans and N-glycopeptides	water	unsatisfactory repeatability	[27]
	histidine-bonded silica	N-glycopeptides from BSA/fetuin mixture digests, human serum tryptic digests	40% ACN/5 mmol/L NH₄HCO₃ (pH 8.2)		[29]
HILIC	TSKgel Amide 80	2-AA-labeled N-glycans of human plasma	80% ACN, 20% 50 mmol/L ammonium formate (pH 4.4)	universality and rapidity, but low selectivity owing	[31]
	Ultimate HILIC amphion column	N-glycopeptides of horseradish per- oxidase, ovalbumin, human holo- transferrin, and human serum	A: 0.1%TFA; B: 0.1%TFA in ACN; 0-20 min, 80%B; 21-30 min, 2%B; 31-38 min, 80%B	to nonspecific adsorption	[33]
	Click Maltose	N-glycopeptides of IgG, BSA and human serum with and without pancreatic tumors	A: 0.1%TFA; B: 0.1%TFA/98% ACN; 0-11 min, 82%B; 11-13 min, 30%B; 13-15 min, 0B		[35]
SEC	oxidized meso- porous carbon ma- terial (O-CMK-3)	N-glycans of hen ovalbumin, BSA, human serum from healthy volun- teers and patients with liver cancer	50% ACN solution	rarely applied, SEC only used as an auxiliary of carbon materials	[36]
PGC-SPE	PGC cartridges	human milk oligosaccharides	20% ACN in water and 40% ACN in 0.05%TFA aqueous solution	universality and high enrichment scale, but	[39]
	PGC cartridges	N-glycans of recombinant human α-galactosidase	steps: 1) 20% ACN in H₂O; 2) 10% ACN in H₂O with 0.05% TFA; 3) 40% ACN in H₂O with 0.05%TFA	unsatisfactory stability and repeatability	[40]
Metal oxides- SPE	combined TiO₂/ZrO₂ resin	N-glycans with mono- or diphospho-esters of recombinant β-glucuronidase	digested with calf intestinal alkaline phosphatase on resin in 50 mmol/L Tris-HCl, pH 9.3, 1 mmol/L MgCl₂, 0.1 mmol/L ZnCl₂, and 1 mmol/L spermidine at 37 ℃ overnight	lack of general applicability	[53]