A Novel Mass Spectrometric Epitope Mapping Approach without Immobilization of the Antibody

El-Kased, Reham F.; Koy, Cornelia; Lorenz, Peter; Montgomery, Helen; Tanaka, Kōichi; Thiesen, Hans‐Jürgen; Glocker, Michael O.

doi:10.4172/jpb.1000160

Cited by 5 publications

(1 citation statement)

References 40 publications

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“…30–32 These epitope mapping methods have over the years reached fairly matured stages and have remarkably advanced either by automation of solution handling procedures 33 or via reducing in-solution handling steps to mixing of antigens and antibodies in ESI-compatible buffer solutions. 34,35 Because direct transition of immune complexes from the condensed phase into the gas phase, which is routinely realized by ESI-MS, 1,10 has been recognized as the key process for successful mass spectrometric epitope mapping, this approach has been termed “intact transition epitope mapping (ITEM).” 35 ITEM-ONE identifies epitopes by determining the mass of the extracted epitope peptide upon dissociation of immune complex ions in the gas phase. 8 Determining kinetic and thermodynamic properties, that is, quantitative traits of immune complexes is possible using the ITEM-TWO method.…”

Section: Introductionmentioning

confidence: 99%

Native and compactly folded in-solution conformers of pepsin are revealed and distinguished by mass spectrometric ITEM-TWO analyses of gas-phase pepstatin A – pepsin complex binding strength differences

Koy,

Glocker,

Danquah

et al. 2023

Eur J Mass Spectrom (Chichester)

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Pepsin, because of its optimal activity at low acidic pH, has gained importance in mass spectrometric proteome research as a readily available and easy-to-handle protease. Pepsin has also been study object of protein higher-order structure analyses, but questions about how to best investigate pepsin in-solution conformers still remain. We first determined dependencies of pepsin ion charge structures on solvent pH which indicated the in-solution existence of (a) natively folded pepsin (N) which by nanoESI-MS analysis gave rise to a narrow charge state distribution with an 11-fold protonated most intense ion signal, (b) unfolded pepsin (U) with a rather broad ion charge state distribution whose highest ion signal carried 25 protons, and (c) a compactly folded pepsin conformer (C) with a narrow charge structure and a 12-fold protonated ion signal in the center of its charge state envelope. Because pepsin is a protease, unfolded pepsin became its own substrate in solution at pH 6.6 since at this pH some portion of pepsin maintained a compact/native fold which displayed enzymatic activity. Subsequent mass spectrometric ITEM-TWO analyses of pepstatin A – pepsin complex dissociation reactions in the gas phase confirmed a very strong binding of pepstatin A by natively folded pepsin (N). ITEM-TWO further revealed the existence of two compactly folded in-solution pepsin conformers (Ca and Cb) which also were able to bind pepstatin A. Binding strengths of the respective compactly folded pepsin conformer-containing complexes could be determined and apparent gas phase complex dissociation constants and reaction enthalpies differentiated these from each other and from the pepstatin A – pepsin complex which had been formed from natively folded pepsin. Thus, ITEM-TWO turned out to be well suited to pinpoint in-solution pepsin conformers by interrogating quantitative traits of pepstatin A – pepsin complexes in the gas phase.

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Section: Introductionmentioning

confidence: 99%

Native and compactly folded in-solution conformers of pepsin are revealed and distinguished by mass spectrometric ITEM-TWO analyses of gas-phase pepstatin A – pepsin complex binding strength differences

Koy,

Glocker,

Danquah

et al. 2023

Eur J Mass Spectrom (Chichester)

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Epitope Mapping: B ‐Cell Epitopes

Pulzová

2018

Encyclopedia of Life Sciences

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Antigen–antibody interaction is a key event in humoral immune response to invading pathogen. All of the macromolecular components of living organism (proteins, carbohydrates, lipids and nucleic acids) are potential antigens. A specific antibody recognises antigen at discrete regions known as antigenic determinants or B‐cell epitopes. Most of the antigen surface may become part of epitopes after recognition with specific antibodies; however, the exact selection mechanism of why certain regions become B‐cell epitopes is not fully understood. The epitope mapping is the process of identification and characterisation of the antibody‐binding site on the antigen, although the term is also applied more broadly to receptor–ligand interactions unrelated to the immune system. With an ever‐increasing number of available pathogen genomes, mapping of epitopes becomes the central issue of vaccine development. Precise identification of epitope is crucial for understanding the molecular basis of immunity and autoimmunity and allows to replace an antigen in the immunisation, antibody production and serodiagnosis. Key Concepts Virtually any surface‐exposed residue of antigen may become part of epitope after interactions with the antibody. The exact selection mechanism governing the antibody recognition of the corresponding epitope is not known. The experimental methods developed to identify the epitopes depend on the unique features of the reaction between an antigen and its complementary antibody. Structural methods interpret the protein structure comprising residues in direct contact with an antibody. Functional methods identify and characterise residues important for binding within structurally defined epitope and are based on detection of binding of antibody to antigen fragments. Identification of B‐cell epitopes is extensively employed in the development of diagnostic tests, therapeutics and vaccines. The epitope‐based subunit vaccines became a promising alternative to traditional vaccines; however, low immunogenicity and low affinity of raised antibodies present major drawbacks of these types of vaccines.

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A novel strategy for the rapid preparation and isolation of intact immune complexes from peptide mixtures

Al-Majdoub

Opuni

Yefremova

et al. 2014

J of Molecular Recognition

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The development and application of a miniaturized affinity system for the preparation and release of intact immune complexes are demonstrated. Antibodies were reversibly affinity-adsorbed on pipette tips containing protein G´ and protein A, respectively. Antigen proteins were digested with proteases and peptide mixtures were exposed to attached antibodies; forming antibody-epitope complexes, that is, immune complexes. Elution with millimolar indole propionic acid (IPA)-containing buffers under neutral pH conditions allowed to effectively isolate the intact immune complexes in purified form. Size exclusion chromatography was performed to determine the integrity of the antibody-epitope complexes. Mass spectrometric analysis identified the epitope peptides in the respective SEC fractions. His-tag-containing recombinant human glucose-6-phosphate isomerase in combination with an anti-His-tag monoclonal antibody was instrumental to develop the method. Application was extended to the isolation of the intact antibody-epitope complex of a recombinant human tripartite motif 21 (rhTRIM21) auto-antigen in combination with a rabbit polyclonal anti-TRIM21 antibody. Peptide chip analysis showed that antibody-epitope binding of rhTRIM21 peptide antibody complexes was not affected by the presence of IPA in the elution buffer. By contrast, protein G´ showed an ion charge structure by electrospray mass spectrometry that resembled a denatured conformation when exposed to IPA-containing buffers. The advantages of this novel isolation strategy are low sample consumption and short experimental duration in addition to the direct and robust methodology that provides easy access to intact antibody-antigen complexes under neutral pH and low salt conditions for subsequent investigations.

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A Novel Mass Spectrometric Epitope Mapping Approach without Immobilization of the Antibody

Cited by 5 publications

References 40 publications

Native and compactly folded in-solution conformers of pepsin are revealed and distinguished by mass spectrometric ITEM-TWO analyses of gas-phase pepstatin A – pepsin complex binding strength differences

Native and compactly folded in-solution conformers of pepsin are revealed and distinguished by mass spectrometric ITEM-TWO analyses of gas-phase pepstatin A – pepsin complex binding strength differences

Epitope Mapping: B ‐Cell Epitopes

A novel strategy for the rapid preparation and isolation of intact immune complexes from peptide mixtures

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