Tian Xu scite author profile

Multilevel proteomics aims to delineate proteins at the peptide (bottom-up proteomics), proteoform (top-down proteomics), and protein complex (native proteomics) levels.Capillary electrophoresis-mass spectrometry (CE-MS) can achieve highly efficient separation and highly sensitive detection of complex mixtures of peptides, proteoforms, and even protein complexes because of its substantial technical progress. CE-MS has become a valuable alternative to the routinely used liquid chromatography-mass spectrometry for multilevel proteomics. This review summarizes the most recent (2019-2021) advances of CE-MS for multilevel proteomics regarding technological progress and biological applications. We also provide brief perspectives on CE-MS for multilevel proteomics at the end, highlighting some future directions and potential challenges.capillary isoelectric focusing-mass spectrometry, capillary zone electrophoresis-mass spectrometry, multilevel proteomics, protein complex, proteoform | INTRODUCTIONProteomics aims to characterize proteins in cells comprehensively as a function of biological conditions, including but not limited to their expression, posttranslational modifications (PTMs), interactions, locations, and turnover (Aebersold & Mann, 2016;Zhang et al., 2013). Mass spectrometry (MS)-based proteomics has become crucial for pursuing better understandings of molecular mechanisms of fundamental cellular processes and disease development (Aebersold & Mann, 2016). There are three main strategies: bottom-up proteomics (BUP), top-down proteomics (TDP), and native proteomics.BUP is the most mature and widely used strategy. It identifies proteins through the MS and tandem MS (MS/MS) measurements of peptides derived from the enzymatic

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Predicting Electrophoretic Mobility of Proteoforms for Large-Scale Top-Down Proteomics

Chen

Lubeckyj

Yang

et al. 2020

Anal. Chem.

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Large-scale top-down proteomics characterizes proteoforms in cells globally with high confidence and high throughput using reversed-phase liquid chromatography (RPLC)–tandem mass spectrometry (MS/MS) or capillary zone electrophoresis (CZE)–MS/MS. The false discovery rate (FDR) from the target–decoy database search is typically deployed to filter identified proteoforms to ensure high-confidence identifications (IDs). It has been demonstrated that the FDRs in top-down proteomics can be drastically underestimated. An alternative approach to the FDR can be useful for further evaluating the confidence of proteoform IDs after the database search. We argue that predicting retention/migration time of proteoforms from the RPLC/CZE separation accurately and comparing their predicted and experimental separation time could be a useful and practical approach. Based on our knowledge, there is still no report in the literature about predicting separation time of proteoforms using large top-down proteomics data sets. In this pilot study, for the first time, we evaluated various semiempirical models for predicting proteoforms’ electrophoretic mobility (μef) using large-scale top-down proteomics data sets from CZE–MS/MS. We achieved a linear correlation between experimental and predicted μef of E. coli proteoforms (R 2 = 0.98) with a simple semiempirical model, which utilizes the number of charges and molecular mass of each proteoform as the parameters. Our modeling data suggest that the complete unfolding of proteoforms during CZE separation benefits the prediction of their μef. Our results also indicate that N-terminal acetylation and phosphorylation both decrease the proteoforms’ charge by roughly one charge unit.

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Deep top-down proteomics revealed significant proteoform-level differences between metastatic and nonmetastatic colorectal cancer cells

McCool

Chen

et al. 2022

Sci. Adv.

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Understanding cancer metastasis at the proteoform level is crucial for discovering previously unknown protein biomarkers for cancer diagnosis and drug development. We present the first top-down proteomics (TDP) study of a pair of isogenic human nonmetastatic and metastatic colorectal cancer (CRC) cell lines (SW480 and SW620). We identified 23,622 proteoforms of 2332 proteins from the two cell lines, representing nearly fivefold improvement in the number of proteoform identifications (IDs) compared to previous TDP datasets of human cancer cells. We revealed substantial differences between the SW480 and SW620 cell lines regarding proteoform and single amino acid variant (SAAV) profiles. Quantitative TDP unveiled differentially expressed proteoforms between the two cell lines, and the corresponding genes had diversified functions and were closely related to cancer. Our study represents a pivotal advance in TDP toward the characterization of human proteome in a proteoform-specific manner, which will transform basic and translational biomedical research.

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Localized Concentration of Semi-Classical States for Nonlinear Dirac Equations

Ding

2014

Arch Rational Mech Anal

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The present paper studies concentration phenomena of the semiclassical approximation of a massive Dirac equation with general nonlinear self-coupling:Compared with some existing issues, the most interesting results obtained here are twofold: the solutions concentrating around local minima of the external potential; and the nonlinearities assumed to be either super-linear or asymptotically linear at the infinity. As a consequence one sees that, if there are k bounded domains j ⊂ R 3 such that −a < min j V = V (x j ) < min ∂ j V , x j ∈ j , then the k-families of solutions w j concentrate around x j as → 0, respectively. The proof relies on variational arguments: the solutions are found as critical points of an energy functional. The Dirac operator has a continuous spectrum which is not bounded from below and above, hence the energy functional is strongly indefinite. A penalization technique is developed here to obtain the desired solutions.

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Tian Xu

Recent advances (2019–2021) of capillary electrophoresis‐mass spectrometry for multilevel proteomics

Predicting Electrophoretic Mobility of Proteoforms for Large-Scale Top-Down Proteomics

Deep top-down proteomics revealed significant proteoform-level differences between metastatic and nonmetastatic colorectal cancer cells

Localized Concentration of Semi-Classical States for Nonlinear Dirac Equations

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