Applications of high performance liquid chromatography-mass spectrometry in proteomics

doi:10.3724/SP.J.1123.2023.11006

Abstract

Abstract:

Proteomics profiling plays an important role in biomedical studies. Proteomics studies are much more complicated than genome research, mainly because of the complexity and diversity of proteomic samples. High performance liquid chromatography-mass spectrometry (HPLC-MS) is a fundamental tool in proteomics research owing to its high speed, resolution, and sensitivity. Proteomics research targets from the peptides and individual proteins to larger protein complexes, the molecular weight of which gradually increases, leading to sustained increases in structural and compositional complexity and alterations in molecular properties. Therefore, the selection of various separation strategies and stationary-phase parameters is crucial when dealing with the different targets in proteomics research for in-depth proteomics analysis. This article provides an overview of commonly used chromatographic-separation strategies in the laboratory, including reversed-phase liquid chromatography (RPLC), hydrophilic interaction liquid chromatography (HILIC), hydrophobic interaction chromatography (HIC), ion-exchange chromatography (IEC), and size-exclusion chromatography (SEC), as well as their applications and selectivity in the context of various biomacromolecules. At present, no single chromatographic or electrophoretic technology features the peak capacity required to resolve such complex mixtures into individual components. Multidimensional liquid chromatography (MDLC), which combines different orthogonal separation modes with MS, plays an important role in proteomics research. In the MDLC strategy, IEC, together with RPLC, remains the most widely used separation mode in proteomics analysis; other chromatographic methods are also frequently used for peptide/protein fractionation. MDLC technologies and their applications in a variety of proteomics analyses have undergone great development. Two strategies in MDLC separation systems are mainly used in proteomics profiling: the “bottom-up” approach and the “top-down” approach. The “shotgun” method is a typical “bottom-up” strategy that is based on the RPLC or MDLC separation of whole-protein-sample digests coupled with MS; it is an excellent technique for identifying a large number of proteins. “Top-down” analysis is based on the separation of intact proteins and provides their detailed molecular information; thus, this technique may be advantageous for analyzing the post-translational modifications (PTMs) of proteins. In this paper, the “bottom-up” “top-down” and protein-protein interaction (PPI) analyses of proteome samples are briefly reviewed. The diverse combinations of different chromatographic modes used to set up MDLC systems are described, and compatibility issues between mobile phases and analytes, between mobile phases and MS, and between mobile phases in different separation modes in multidimensional chromatography are analyzed. Novel developments in MDLC techniques, such as high-abundance protein depletion and chromatography arrays, are further discussed. In this review, the solutions proposed by researchers when encountering compatibility issues are emphasized. Moreover, the applications of HPLC-MS combined with various sample pretreatment methods in the study of exosomal and single-cell proteomics are examined. During exosome isolation, the combined use of ultracentrifugation and SEC can yield exosomes of higher purity. The use of SEC with ultra-large-pore-size packing materials (200 nm) enables the isolation of exosomal subgroups, and proteomics studies have revealed significant differences in protein composition and function between these subgroups. In the field of single-cell proteomics, researchers have addressed challenges related to reducing sample processing volumes, preventing sample loss, and avoiding contamination during sample preparation. Innovative methods and improvements, such as the utilization of capillaries for sample processing and microchips as platforms to minimize the contact area of the droplets, have been proposed. The integration of these techniques with HPLC-MS shows some progress. In summary, this article focuses on the recent advances in HPLC-MS technology for proteomics analysis and provides a comprehensive reference for future research in the field of proteomics.

Key words: high performance liquid chromatography (HPLC), reversed-phase liquid chromatography (RPLC), hydrophilic interaction liquid chromatography (HILIC), hydrophobic interaction chromatography (HIC), ion exchange chromatography (IEC), size-exclusion chromatography (SEC), proteomics

CLC Number:

O658

LIU Wei, WENG Lingxiao, GAO Mingxia, ZHANG Xiangmin. Applications of high performance liquid chromatography-mass spectrometry in proteomics[J]. Chinese Journal of Chromatography, 2024, 42(7): 601-612.

Figures/Tables 6

Fig. 1 Schematic diagram of online HILIC-RPLC two-dimensional separation[22] HILIC: hydrophilic interaction liquid chromatography; RPLC: reversed-phase liquid chromatography.

Table 1 Chromatographic modes and column packing parameters for intact protein separation

Analytes	Separation mode	Pore size/nm	Particle size/μm	Refs.
Rat or human liver protein lysate	SCX	30	5	[39,40]
	RPLC	30	5
Human plasma	SAX	100	10	[41]
	RPLC	30	5
HeLa or E. coli cell protein lysate	high-pH RPLC	30	3.5	[42,43]
	low-pH RPLC	30	5
Caco-2 cell protein lysate	high-pH RPLC	100	8	[44]
	low-pH RPLC	30	3.5
MCF10A cell protein lysate	SCX	30	5	[45]
	RPLC	/	5
Myoglobin	SEC	30	2.7	[46]
Bovine serum albumin, thyroglobulin, pyruvate kinas, γ-globulin, trastuzumab, L-asparaginase, transferrin, ovalbumin, RNase A, uracil	SEC	25	4	[47]

Fig. 2 RPLC-based online two-dimensional separation strategy[43] Reprinted with permission from Anal Chem, 2020, 92, 19, 12774. Copyright ? 2020, American Chemical Society.

Fig. 3 Separation strategy for protein complexes a. protein and protein complex mass distribution; b. the array-based online IEC-RPLC platform for protein complex separation[66].

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