Native Ion Mobility Mass Spectrometry: When Gas-Phase Ion Structures Depend on the Electrospray Charging Process

Khristenko, Nina A.; Amato, Jussara; Livet, Sandrine; Pagano, Bruno; Randazzo, Antonio; Gabelica, Valérie

doi:10.1007/s13361-019-02152-3

Cited by 31 publications

(46 citation statements)

References 59 publications

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“…We wondered if these findings could be due to structural changes of the DNA happening in the gas phase of the mass spectrometer. The study of biomolecular structure in the solution and gas phase is an active field of research, and both experimental and computational approaches have recently made significant progress in our understanding of the explicit role of solvation, and the consequences of its removal during the electrospray process 49 , 50 . Structures such as the large diameter barrels can obviously fluctuate and are in fact expected to undergo compaction in the gas phase due to the absence of water and the desire to self-solvate.…”

Section: Resultsmentioning

confidence: 99%

Sizing up DNA nanostructure assembly with native mass spectrometry and ion mobility

et al. 2022

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Recent interest in biological and synthetic DNA nanostructures has highlighted the need for methods to comprehensively characterize intermediates and end products of multimeric DNA assembly. Here we use native mass spectrometry in combination with ion mobility to determine the mass, charge state and collision cross section of noncovalent DNA assemblies, and thereby elucidate their structural composition, oligomeric state, overall size and shape. We showcase the approach with a prototypical six-subunit DNA nanostructure to reveal how its assembly is governed by the ionic strength of the buffer, as well as how the mass and mobility of heterogeneous species can be well resolved by careful tuning of instrumental parameters. We find that the assembly of the hexameric, barrel-shaped complex is guided by positive cooperativity, while previously undetected higher-order 12- and 18-mer assemblies are assigned to defined larger-diameter geometric structures. Guided by our insight, ion mobility-mass spectrometry is poised to make significant contributions to understanding the formation and structural diversity of natural and synthetic oligonucleotide assemblies relevant in science and technology.

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Section: Resultsmentioning

confidence: 99%

Sizing up DNA nanostructure assembly with native mass spectrometry and ion mobility

et al. 2022

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“…The gasphase compaction at low charge states was discussed before for DNA single strands, 48 DNA and RNA duplexes, 49 and DNA i-motifs. 50 At charge state 7-, the nonspecific interactions of the nonfolded forms are mostly broken, whereas those of the G-quadruplex persist up to higher internal energies. Charge states 7-and higher can be obtained only with the addition of sulfolane.…”

Section: Resultsmentioning

confidence: 99%

Probing ligand and cation binding sites in G-quadruplex nucleic acids by mass spectrometry and electron photodetachment dissociation sequencing

Paul

Marchand

Verga

et al. 2019

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“…However, for molecules in which backbones can rearrange in the gas phase (or in the final desolvation/declustering stages of the electrospray process) to make nonspecific interactions, how can one infer a solution conformation (or conformational ensemble) from a collision cross section distribution? This is where we reach the current limits of structural ion mobility spectrometry: control experiments hint at the preservation of some memory of the solution conformation, yet the conformation is affected by the measurement, for example, by the electrospray charging process, ion internal energy, and time spent in the gas phase. The charging process is critical for nucleic acid rearrangements, as the phosphate groups are positioned along the backbone, and partial neutralization provides protons that can form non-native hydrogen bonds and which could be mobile …”

Section: Nucleic Acid Structures In the Gas Phasementioning

confidence: 99%

Native Mass Spectrometry and Nucleic Acid G-Quadruplex Biophysics: Advancing Hand in Hand

Gabelica

2021

Acc. Chem. Res.

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Conspectus While studying nucleic acids to reveal the weak interactions responsible for their three-dimensional structure and for their interactions with drugs, we also contributed to the field of biomolecular mass spectrometry, both in terms of fundamental understanding and with new methodological developments. A first goal was to develop mass spectrometry approaches to detect noncovalent interactions between antitumor drugs and their DNA target. Twenty years ago, our attention turned toward specific DNA structures such as the G-quadruplex (a structure formed by guanine-rich strands). Mass spectrometry allows one to discern which molecules interact with one another by measuring the masses of the complexes, and quantify the affinities by measuring their abundance. The most important findings came from unexpected masses. For example, we showed the formation of higher- or lower-order structures by G-quadruplexes used in traditional biophysical assays. We also derived complete thermodynamic and kinetic description of G-quadruplex folding pathways by measuring cation binding, one at a time. Getting quantitative information requires accounting for nonspecific adduct formation and for the response factors of the different molecular forms. With these caveats in mind, the approach is now mature enough for routine biophysical characterization of nucleic acids. A second goal is to obtain more detailed structural information on each of the complexes separated by the mass spectrometer. One such approach is ion mobility spectrometry, and even today the challenge lies in the structural interpretation of the measurements. We showed that, although structures such as G-quadruplexes are well-preserved in the MS conditions, double helices actually get more compact in the gas phase. These major rearrangements forced us to challenge comfortable assumptions. Further work is still needed to generalize how to deduce structures in solution from ion mobility spectrometry data and, in particular, how to account for the electrospray charging mechanisms and for ion internal energy effects. These studies also called for complementary approaches to ion mobility spectrometry. Recently, we applied isotope exchange labeling mass spectrometry to characterize nucleic acid structures for the first time, and we reported the first ever circular dichroism ion spectroscopy measurement on mass-selected trapped ions. Circular dichroism plays a key role in assigning the stacking topology, and our new method now opens the door to characterizing a wide variety of chiral molecules by mass spectrometry. In summary, advanced mass spectrometry approaches to characterize gas-phase structures work well for G-quadruplexes because they are stiffened by inner cations. The next objective will be to generalize these methodologies to a wider range of nucleic acid structures.

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Native Ion Mobility Mass Spectrometry: When Gas-Phase Ion Structures Depend on the Electrospray Charging Process

Cited by 31 publications

References 59 publications

Sizing up DNA nanostructure assembly with native mass spectrometry and ion mobility

Sizing up DNA nanostructure assembly with native mass spectrometry and ion mobility

Probing ligand and cation binding sites in G-quadruplex nucleic acids by mass spectrometry and electron photodetachment dissociation sequencing

Native Mass Spectrometry and Nucleic Acid G-Quadruplex Biophysics: Advancing Hand in Hand

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