Mass spectrometric and bio-computational binding strength analysis of multiply charged rnase s gas-phase complexes obtained by electrospray ionization from varying in-solution equilibrium conditions

Cornelia Koy, Kwabena F.M. Opuni, Bright D. Danquah, Andrei Neamtu, Michael O. Glocker

Research output: Contribution to journalArticlepeer-review

7 Citations (Scopus)

Abstract

We investigated the influence of a solvent’s composition on the stability of desorbed and multiply charged RNAse S ions by analyzing the non-covalent complex’s gas-phase dissociation processes. RNAse S was dissolved in electrospray ionization-compatible buffers with either increasing organic co-solvent content or different pHs. The direct transition of all the ions and the evaporation of the solvent from all the in-solution components of RNAse S under the respective in-solution conditions by electrospray ionization was followed by a collision-induced dissociation of the surviving non-covalent RNAse S complex ions. Both types of changes of solvent conditions yielded in mass spectrometrically observable differences of the in-solution complexation equilibria. Through quantitative analysis of the dissociation products, i.e., from normalized ion abundances of RNAse S, S-protein, and S-peptide, the apparent kinetic and apparent thermodynamic gas-phase complex properties were deduced. From the experimental data, it is concluded that the stability of RNAse S in the gas phase is independent of its in-solution equilibrium but is sensitive to the com-plexes’ gas-phase charge states. Bio-computational in-silico studies showed that after desolvation and ionization by electrospray, the remaining binding forces kept the S-peptide and S-protein together in the gas phase predominantly by polar interactions, which indirectly stabilized the in-bulk solution predominating non-polar intermolecular interactions. As polar interactions are sensitive to in-solution protonation, bio-computational results provide an explanation of quantitative experimental data with single amino acid residue resolution.

Original languageEnglish
Article number183
JournalInternational Journal of Molecular Sciences
Volume22
Issue number19
DOIs
Publication statusPublished - Oct 2021

Keywords

  • Binding strength
  • Bio-computation
  • Desolvation process
  • ESI-MS
  • ITEM-TWO
  • In-silico modeling
  • Non-covalent complex
  • RNAse S

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